Wireless proximity aware remote control lighting system

ABSTRACT

Aspects of the present invention further include a lighting system comprising a lighting source, a connector in electrical communication with the lighting source and an external power source, an energy storage device, an input device, and a controller. The controller may be configured to identify the presence of a load indicator signal received via the input device, determine whether the load indicator signal indicates a load-reducing state, and when the load indicator signal indicates the load-reducing state, discharge the energy storage device to maintain an intensity of the lighting source.

RELATED APPLICATIONS

The present application is a continuation of U.S. application Ser. No. 13/446,674, filed Apr. 13, 2012 which claims the benefit of priority from U.S. Provisional Patent Application No. 61/475,931 filed Apr. 15, 2011, the entire contents of each of which is incorporated herein by reference.

BACKGROUND

The present invention is directed generally to devices and applications for the use of wireless control and wireless power in lighting devices. More particularly, the invention relates to the use of wireless control and wireless power in light emitting diode (LED) based devices primarily for illumination purposes.

Conservation and management of electrical power are a growing concern with regard to both cost and environmental impact. In various lighting applications, the use of light emitting diodes (LEDs) for illumination is beginning to emerge as a lighting source with potential for addressing these concerns. LED light sources have a long life, are energy efficient, are durable and operate over a wide temperature range. While LED lighting is becoming an attractive option for certain applications, it is not optimal for many applications. Therefore, there is a need for improved LED lighting systems.

SUMMARY

The present invention is directed generally to devices and applications related to the use of wireless control and wireless power in light emitting diode (LED) based lighting devices. More particularly, the devices and applications according to various embodiments of the present invention make use of wireless control and wireless power in lighting devices to provide advantages that may include increased ease of installation, increased ability to install lighting in locations independent of a connection to wired power, increased cost savings, increased energy efficiency, reduced energy consumption at times of peak demand through controls and power management and in safety, security, and increased convenience for the end user.

One embodiment of the invention is directed to an externally controllable LED light in a bulb-type housing, tube, lamp, fixture, retrofit fixture, and the like, that may receive commands from a power company or lighting control software to control the wireless power source. For example, a load control switch or demand response mechanism reducing light intensity may be designed to control lighting to reduce power consumption during periods of peak usage of electricity. In an exemplary application of reducing the intensity of the lights, the present invention may supplement power switched off or reduced by the power company or lighting control software via battery power, thus enabling the light to stay at the same intensity level while still reducing the power consumed from the AC power source. The source of the load control signal may be external to the externally controllable LED light. This process may be referred to as “grid shifting” or storing energy from the grid (e.g., an external power grid) to a power source that is integrated or otherwise associated with the light at one time and using that stored energy at another time. A power source that is integrated or otherwise associated with the light will be referred to herein as an “integrated” power source. However, it is to be understood that such a power source need not necessarily be located within the same housing as the light and may, for example, be located externally to the light. Grid shifting may allow the light to be moved on and off of the AC power source using the integrated power source as an alternate power source and the control of these and other functions with external signals. In some embodiments, AC power and the integrated power source may be used simultaneously when, for example, the load is shared by the power sources. In such a case, the load on the AC power source may be reduced by some amount by transferring some amount of load to the integrated power source. The externally controllable LED light may also contain any form of wireless control which can also be controlled by the power company or lighting control software to enable, disable or set the functionality of the wireless control mechanism.

These and other systems, methods, objects, features, and advantages of the present invention will be apparent to those skilled in the art from the following detailed description of the preferred embodiment and the drawings. All documents mentioned herein are hereby incorporated in their entirety by reference.

Aspects of the present invention include a lighting system comprising a lighting source, a connector in electrical communication with the lighting source and an external power source, an energy storage device, an input device, and a controller. The controller may be configured to identify the presence of a load indicator signal received via the input device, determine whether the load indicator signal indicates a load-reducing state, and when the load indicator signal indicates the load-reducing state, discharge the energy storage device to maintain an intensity of the lighting source.

Aspects of the present invention further include a lighting system comprising a lighting source, a connector in electrical communication with an external power source, an energy storage device, an input device, and a controller configured to manage power usage of the lighting source based on one or more of a signal generated by the input device, an internal timer, or an internal clock.

Aspects of the present invention further include a lighting system comprising a lighting source and a controller. The controller may be configured to determine an intensity of light emitted by the lighting source while the lighting source draws a first amount of power from an external power source, identify a load indicator signal, determine whether the load indicator signal indicates a load-reducing state, and when the load indicator signal indicates the load-reducing state determine a second amount of power for the lighting source to draw from the external power source, and determine a third amount of power for the lighting source to draw from the energy storage device, wherein drawing the second and third amounts of power causes the lighting source to emit light at the determined intensity.

Aspects of the present invention further include a method comprising determining an intensity of light emitted by a lighting source while the lighting source draws a first amount of power from an external power source, identifying a load indicator signal, determining whether the load indicator signal indicates a load-reducing state, and when the load indicator signal indicates the load-reducing state determining a second amount of power for the lighting source to draw from the energy storage device, and determining a third amount of power for the lighting source to draw from the external power source, wherein drawing the second and third amounts of power causes the lighting source to emit light at the determined intensity.

These and other systems, methods, objects, features, and advantages of the present invention will be apparent to those skilled in the art from the following detailed description of the preferred embodiment and the drawings. All documents mentioned herein are hereby incorporated in their entirety by reference.

BRIEF DESCRIPTION OF THE FIGURES

The invention and the following detailed description of certain embodiments thereof may be understood by reference to the following figures:

FIG. 1 shows a method of grid shifting that allows the load to be shared between two or more power sources;

FIG. 2 shows a block diagram of a battery backed LED driver module;

FIG. 3 shows a block diagram of a grid shifting system containing an energy storage device in the electrical fixture;

FIG. 4 shows a block diagram of a grid shifting system containing an energy storage device in an external grid shifting controller;

FIG. 5 shows a block diagram of a grid shifting system for lighting devices with an energy storage device in the lighting device;

FIG. 6 shows a block diagram of a grid shifting system for lighting devices with an energy storage device in the external grid shifting controller;

FIG. 7A shows a block diagram of a lighting device with internal timing for grid shifting;

FIG. 7B shows a flow diagram of a lighting device with internal timing for grid shifting;

FIG. 8A shows a block diagram of a lighting device with time of day inference for grid shifting;

FIG. 8B shows a flow diagram of a lighting device with time of day inference for grid shifting.

FIG. 9A shows a block diagram of a lighting device shifting a lighting load off the grid based on internally derived information;

FIG. 9B shows a flow diagram of a lighting device shifting a lighting load off the grid based on internally derived information;

FIG. 10A shows a block diagram of a lighting device shifting a lighting load off the grid based on an internal power source performance characteristic;

FIG. 10B shows a flow diagram of a lighting device shifting a lighting load off the grid based on an internal power source performance characteristic;

FIG. 11A shows a block diagram of a lighting device shifting a lighting load off the grid based on internally derived information associated with an energy distribution grid demand parameter;

FIG. 11B shows a flow diagram of a lighting device shifting a lighting load off the grid based on internally derived information associated with an energy distribution grid demand parameter;

FIG. 12 depicts an embodiment of an emergency lighting system;

FIG. 13 depicts an embodiment of a wireless lighting module;

FIG. 14 depicts an embodiment of a switch sensing lighting unit; and

FIG. 15 shows a block diagram of a lighting system capable of reducing the power consumption while maintaining the normal light intensity levels.

While the invention has been described in connection with certain preferred embodiments, other embodiments would be understood by one of ordinary skill in the art and are encompassed herein.

DETAILED DESCRIPTION

The claimed subject matter is described with reference to the drawings, wherein like reference numerals are used to refer to like elements throughout. In the following description, for purposes of explanation, specific details may be set forth in order to provide a thorough understanding of the subject innovation. It may be evident, however, that the claimed subject matter may be practiced without these specific details. In other instances, well-known structures and devices are shown in block diagram form in order to facilitate describing the subject innovation. Moreover, The drawings may not be to scale.

In embodiments of externally powered battery embedded wireless lighting devices, a lighting device or lighting system capable of maintaining light intensity under demand response control may be implemented by designing a receiver into the device that may receive a load shed signal or command wirelessly or over existing electrical wiring such that the lighting device or lighting system may either turn off lights, change lighting intensity levels or that the lighting device or lighting system may consume some or all of the energy that is consumed over to an embedded battery or other form of wireless power. In one example, the lighting device or lighting system may reduce the power consumption from the power company but maintain certain light intensity levels (the light intensity level prior to receipt of the load control command) by supplying some power from stored power in the lighting device or lighting system. In some embodiments, the demand response control may maintain any light intensity level configured by the demand response control that may require the lighting device or lighting system to consume some or all of the energy from the embedded energy storage device wherein the light intensity level may be lower or higher than the normal light intensity level. In alternate examples, more than one power source external to the lighting device or lighting system may supply power to the lighting device or lighting system and the device may be controlled to determine how much power to consume from each of the more than one power sources. In an embodiment, an externally powered battery embedded wireless lighting device may be programmed to grid shift based on a time maintained in the device. The programming may be preconfigured or may be received as part of the configuration of the lighting device or lighting system provided by the load shed command.

In embodiments of lighting devices and lighting systems, there may be a need for the development of lighting devices or lighting systems that may be powered by a power source off of the grid during times of peak power demand from a utility. Demand response mechanisms may allow for a reduction of power consumption in response to periods of peak demand or dynamic changes in pricing of electricity. In lighting, demand response is currently implemented by dimming lighting. By way of an example, if a 25% reduction in power consumption is required by the lighting component of an energy consumer, lighting is dimmed to a level to reduce the power consumed by 25%. If the light sources contain an energy storage device, the 25% may be transitioned to be supplied by the energy storage device thus allowing for full light intensity through the time of peak demand. Thus, a light source that can automatically shift some of the load off grid based on time or a light source with demand response capabilities that can receive an explicit request to change its behavior and respond to the request by moving some or all of the load off grid would be able to offer benefits beyond what a simple dimming of the lights can achieve.

In some embodiments, a “peak shedding” algorithm may be implemented such that a peak in energy usage that can be measured may be responded to by an automatic reduction of energy usage. Peak shedding or “load leveling” (which may, in some senses, be equivalent to peak shedding and/or grid shifting) may be performed automatically by an energy consumer may allow an energy consumer to not exceed some threshold of energy use. In some cases, billing rates are calculated based on the peaks of energy usage. Peak shedding or load leveling may be implemented through a measurement of power consumption at a given, desired time. Alternately, it may be implemented based on time of day and calendar scheduling. Power usage through the day and through the calendar year may be well known by an end consumer or energy producer. Scheduling some amount of power consumed to a local energy storage device at the right times has the ability to reduce peak usage. Many end devices operating synchronized to time of day and calendar can reduce the load. Less infrastructure might be required if a lighting device has some intelligence built in and the ability to shift off grid based on time or other detected conditions.

Lighting infrastructure may benefit where there are regular or planned disruptions in power allowing the infrastructure to remain powered and illuminated during the disruption or reduce power consumption from the external power source (e.g., grid power). Large organizations might have backup generators and other bulk energy storage devices to serve as backup power during these types of disruptions however smaller businesses, retail, manufacturing and the like may need to stop work during an outage. Inadequate lighting may result in a reduction in productivity. Inadequate lighting may be the result during times when the lights are dimmed to reduce power consumption. Resulting loss of productivity may be avoided or decreased by moving the necessary reduction of power consumption to a local power source. A distributed power storage network makes sense for small and medium sized businesses because it scales better than large backup power installations.

In one embodiment of grid shifting, a peak shedding module may be designed with an integrated power source, such as a rechargeable battery, to store and use power from the integrated power source, an input power connection, an output power connection and may contain the ability to identify or receive an indication of a peak in power usage and transition some or all of the power required by a connected load to the integrated power source. The functionality (e.g., the functionality enabling grid shifting, peak shedding or load leveling) may be pre-programmed, factory set, designed in a custom electrical circuit or the like to respond to sensors on the module or measurements of power usage made by the module and may contain a pre-programmed algorithm to implement the peak shedding function. The functionality may be learned using sensors on the module or measurements of power usage made by the module and an intelligent program (as used herein, the term “intelligent” denotes a capability of responding to a particular input, where “input” can include either locally generated input, including, for example, input from an internal timer or time of day clock, or externally as well as pre-programmed operation) that may change the behavior of the module based on the feedback received from sensors or measurement devices on the module. The sensors or measurements may include a light sensor, motion sensor, an atomic clock or time receiver, temperature sensor or any other sensor mentioned herein, a measurement of power usage, a record of power usage over time, or other measurement of the characteristics of the power that may be detected by the module that may allow the peak shedding function to meet requirements. In some embodiments, there may not be a sensor on the module and the peak shedding function is performed based on a program. The program may contain a real time clock that may be set by the user such that the intelligent program may use time of day or a calendar to perform the peak shedding functionality. The peak shedding function may be used for cost savings, energy efficiency or a reduction in demand. A peak shedding module may allow the power usage of an electrical circuit to be averaged over time so that an individual peak in the use of power no longer occurs or is reduced. The peak shedding module may have switches, dials, knobs etc on the module to set time of day, sensor or measurement thresholds such that a user may be able to control how the intelligent program manages the peak shedding module. The peak shedding module may act based on those settings and/or the pre-programmed or designed function. The settings may be changed by the user.

In some embodiments, the peak shedding module may record a moving average of the power usage on the electrical circuit it is connected to. The peak shedding module may make an “instantaneous measurement” (herein used to refer to a measurement at a particular, chosen time) of power consumption of the electrical circuit. If the instantaneous measurement of power consumption of the electrical circuit exceeds some threshold, the peak shedding module may automatically transition some amount of power consumption to the integrated power source. In embodiments, the peak shedding module may receive measurement information from a remote measurement device at any point in the power distribution installation that may communicate by wired or wireless communication method the measurement information or a command derived from an analysis of the measurement information to perform the load reduction operation. The measurement information may be received by an intermediate processor that may be programmed to send control to the peak shedding module to perform the peak shedding function accordingly. The peak shedding module may be able to transition power consumed on the electrical circuit quickly enough that it may reduce the subsequent peak in power consumption. The peak shedding module may make adjustments over time based on the average power consumption such that it may adjust the threshold at which the peak shedding module begins to adjust power consumption.

To implement the sharing of power, the peak shedding module may monitor the power consumed by the electrical circuit from the input power. By way of an example, a resistor may be inserted in-line with the input power to output power connection in the peak shedding module and a voltage drop across the resistor may allow the peak shedding module to measure power being drawn from the input. The peak shedding module may have a diode OR connection to the power output such that the input power and power sourced from the integrated power source, such as a rechargeable battery, may be shared. A constant current circuit may be connected at the output of the rechargeable battery. By way of an example, an LM317 configured as a constant current source may be connected at the output of the battery with a programmable resistor in the circuit such that an external device, such as a microcontroller or microprocessor, may be able to change the amount of current sourced from the battery. By way of an example, a microcontroller that may be able to measure the power being drawn from the input power source may contain a program such that when the measured input power exceeds a programmed threshold, the microcontroller may adjust the resistance of the programmable resistor to set the current supplied from the battery. In supplying current from the battery, the amount of power required from the input source may be reduced. By way of an example, in providing power to the electrical circuit, the input power consumption exceeds the threshold set in the microcontroller. The microcontroller may adjust the resistor in the constant current circuit as supplied from the battery to assume five percent of the power supplied. In response the input power consumption will be reduced. The microcontroller may make another measurement of the input power consumption and adjust the supply from the battery and so on. The frequency of the measurements and adjustments may be any rate as required by the application. In an embodiment, the sharing of power is done by FETs which may be PWM controlled from a device such as a microcontroller such that the power supplied from the input power source and the integrated power source may be adjusted using PWM to change the amount of power drawn from each source. In an embodiment, the peak shedding module may have a relay and switching circuit where it may perform a time division multiplexing function to control the amount of power consumed from each power source.

In some embodiments of the peak shedding module, there may be a communication interface such that the module may communicate with an external source by wired connection over a power distribution network, for example on the AC power lines (X10, INSTEON, Broadband over Power Lines, proprietary communication scheme etc), or wirelessly through a wireless interface (dedicated RF communication link, ZIGBEE, WIFI, ENOCEAN, BLUETOOTH etc). By way of an example, the electric company may control or gather status from peak shedding modules throughout its power distribution network to remotely offload power usage at times when power demand is high or is peaking by commanding some portion or the entire distributed network of peak shedding modules to battery backup. A peak shedding module may be used with one or more devices on an electrical circuit such that the module may monitor and/or supply power to the one or more devices as determined by the peak shedding module as described herein. In embodiments, the one or more devices may be a lighting device, lighting adapter, lighting fixture, troffer, lamp or lamp base, ballast, lighting power supplies, lighting control device and the like, television, television peripheral, computer, servers, network equipment, storage devices, appliance, washer, clothes dryer, refrigerator, freezer, electric range, microwave oven, electric water heater, vacuum cleaner, cell phone charger, stereo, air conditioner, HVAC devices, electric or hybrid vehicles, electric motors, portable generators and backup power sources, uninterruptable power supplies (UPS), inverters, industrial and manufacturing machinery etc. In some embodiments, the peak shedding module may be connected to one or more electrical circuits in a facility. By way of an example, a lighting circuit controlled by a peak shedding module at a circuit breaker for the lighting circuit may receive a command from an external source such as a building management system to shift some amount of power required by the circuit to the integrated rechargeable battery. The embedded power source of the peak shedding module may be any suitable size. By way of an example, a peak shedding module may contain an AC input, an AC output, an embedded rechargeable battery and the circuitry required to supply power from the AC input, the integrated power source or both. In one example, the peak shedding module may be integrated into a refrigerator such that it may shift some of the load off of the grid and alternatively allow the refrigerator to continue to operate during the power outage for a duration enabled by the capacity of the embedded power source. In one embodiment, a refrigerator may have one compartment that is controlled by the peak shedding module such that even if other portions of the refrigerator may not remain cool, the one compartment will continue to be powered by the embedded power source.

In embodiments, a refrigerator may have one compartment inside the refrigerator that is capable of off grid operation. In embodiments, the battery backed up refrigerator compartment would consume considerably less power because it is one smaller compartment and thus may be able to continue refrigeration for a longer period of time using battery power. In embodiments, the internal battery backed up refrigerator compartment may also benefit from the fact that it is inside a refrigerated unit. By way of an example, the refrigeration system of the battery backed up compartment may be smaller because it may not have to consume as much energy to maintain refrigeration. In such a case, during a power outage, it may provide days of refrigeration. In one embodiment, the battery backed up refrigerator compartment comprises of a rechargeable battery, power input, insulated housing with access door or drawer, heat exchanger and a thermostat. In some embodiments, the thermostat measures a higher temperature or a rise in temperature outside of the battery backed up refrigerator compartment and turns on the heat exchanger powered by the battery backup to begin cooling inside the compartment. In some embodiments, there may not be a thermostat and instead the battery backed up refrigerator compartment detects a power failure by monitoring the power input to the compartment. The power input may be a DC power input or an AC power input. The power input may interface to any power source available inside the refrigerator to receive external power. The external power received at the power input may be used to charge the battery. In some embodiments, the external power connection may provide power to the battery backed up refrigerator compartment at all times except when there is a power failure. In one embodiment, a retrofit system includes a battery backed up refrigerator compartment, an LED light bulb that can be installed in the refrigerator light socket and wiring between the refrigerator compartment and LED light bulb. In such a system, the battery backed up refrigerator compartment may slide onto a shelf inside the refrigerator and the LED light bulb may be installed into the refrigerator light socket to deliver power to the battery backed up refrigerator compartment to keep the battery charged. In some embodiments, the controlling switch may be disabled to allow power to always be available at the LED light bulb. In some embodiments, the LED light bulb may have a light sensor and the intelligence to not illuminate the light bulb when a low level of ambient light is measured while the refrigerator door is closed therefore it may be used in a light socket within the refrigerator that may always have power applied. The architectures described herein for grid shifting systems may be applied to a battery backup system for a refrigerated compartment within a refrigerator for use during a power failure.

In embodiments using the peak shedding module, a peak shedding system may be created using several peak shedding modules to distribute the implementation of peak shedding throughout a facility. By way of an example, a residence may contain a peak shedding module on multiple or even every electrical circuit in the residence. Each individual peak shedding module may make adjustments as required by the electrical circuit it is performing the peak shedding function on. In such a manner, the distributed peak shedding function implemented by the peak shedding system may reduce or eliminate a peak power condition from the electric company. In some embodiments, the peak shedding modules may be designed into a single control panel. In embodiments, the peak shedding modules may be integrated into the circuit breaker panel. In some embodiments a peak shedding module may be used on multiple electrical circuits simultaneously. By way of an example, a grid shifting circuit breaker panel may be designed to be installed or retrofit where a circuit breaker panel may be typically installed. It is to be appreciated that a peak shedding module may be any size and may use a rechargeable battery of any size to meet the requirements of the application.

In embodiments, the present invention may provide for a power outage lighting management within an environment, comprising a power outage detection device adapted to detect a power outage condition and to wirelessly transmit power outage indication data to a plurality of lighting systems within the environment, where at least one of the plurality of lighting systems include an LED light source that is powered by an internal power source. The plurality of lighting systems may include a light source that is powered selectively by either the internal power source or an external power source. In response to receiving the power outage power indication data, the lighting system including the LED light source that is powered by the internal power source may regulate a light intensity of the LED light source in accordance with the power outage indication data, such as the light intensity as a dimmed light condition, the light intensity as a full brightness light condition or other condition.

In embodiments, the present invention may provide for a power outage management for a plurality of lighting sources, comprising, for example, a plurality of lighting facilities containing an LED lighting source, a power outage input device, an internal power source, a control facility for manipulating the light output of the LED lighting source, and the like, wherein the lighting facility may provide light in response to a power outage signal received by the power outage input device indicating a power outage condition; and a power outage detection device that monitors power at some point in power distribution to detect the power outage condition, where the power outage detection device may wirelessly transmit the power outage signal to the power outage input device of the at least one of the plurality of lighting facilities when the power outage condition is detected. In embodiments, the outage input device may contain a wireless receiver to receive the power outage signal. The response may be provided with an environmental input from a sensor input device in the lighting facility in addition to the signal received by the power outage input device. The lighting facility may take the form of at least one of a light bulb capable of mounting into a lighting fixture, a lighting fixture, a retrofit lighting fixture, a lighting adapter, a battery powered lighting fixture, and the like. The centralized controller may be running a software control program. The signal may be received from a web-based source. The web-based source may be on a local network, on the Internet, and the like. The internal power source may be a rechargeable energy storage device integrated with the lighting facility that is capable of supplying power to the lighting facility independent of the power distribution, and where the recharging may be provided internal to the lighting facility at a time when the power distribution is available. The rechargeable energy storage device internal to the lighting facility may be a battery, fuel cell, super capacitor, and the like. The internal power source may be a non-rechargeable power source such as an alkaline battery. The lighting facility may be disconnected and used as a portable lighting device. The sensor may sense infrared, temperature, light, motion, acoustic, smoke, electromagnetic, vibration or other suitable input. The manipulating may include, for example, switching on the light output, changing the illumination level of the light output, flashing the light output, changing the color content of the light output, and the like. The power outage module may contain an integral power source. The power outage module may contain a light source, where the power outage module may be disconnected from a power source and used as a portable lighting device. The response may be provided with an environmental input from a sensor input device in the centralized controller. The centralized controller may contain pushbuttons, switches, dials, and the like to control the lighting facilities remotely. The centralized controller may be a power outage module monitoring an emergency lighting circuit to detect an indication that emergency lighting must be activated. In this way, the power outage device may be connected to an emergency lighting circuit (e.g., not part of power distribution) but it may allow a wireless extension of the emergency lighting circuit. In some embodiments, the power outage module may be plugged into a wall outlet, screwed into an Edison socket or the like. In embodiments, the present invention may provide a detached lighting system that could be supplemental to an installed emergency lighting system by propagating the control through a connected power outage device to the lights and as such provide a full off the grid power outage lighting system.

In embodiments of an intelligent wall switch, a wall switch may be designed to include a charging mode that may allow the switch to be closed to allow charging of a rechargeable integrated power source in the devices or on the circuit that it is controlling. The intelligent wall switch may provide a change in the electrical characteristics of the line to allow devices on the circuit to detect different modes. By way of an example, a device with a switch sense circuitry may be able to detect charging mode remotely by measuring some electrical characteristic of the branch circuit and change state appropriately. In this example, detecting charging mode may allow a device to charge a rechargeable integrated power source without powering the device for normal operation.

In embodiments, an intelligent grid shifting system may be constructed using an intelligent wall switch and a device with a rechargeable integrated power source with the ability of the intelligent wall switch to enter a charge mode that the end device may detect or may be programmed to enter into a charge mode simultaneously with the wall switch. In some embodiments, the intelligent wall switch and/or grid shifting device may be programmed directly at the switch or device via some user interface with the configuration maintained on the switch or device. In embodiments, the intelligent grid shifting system may communicate with control systems for status and control of the grid shifting function provided by the intelligent grid shifting system. In some embodiments, the intelligent wall switch includes the ability to communicate via wired or wireless connection as mentioned herein. In embodiments, the intelligent wall switch and/or grid shifting device may be programmed, configured or queried via the wired or wireless communication interface by an external controller. In charge mode, the intelligent wall switch may automatically close the wall switch or bypass the wall switch allowing power to be applied to the circuit at times when power was not intended to be applied to the circuit. If the end device may detect that the power is applied but the mode is charge mode, the end device may use the applied power only for charging purposes. The end device may detect charge mode using switch sense functionality, using a communication mechanism over the circuit, by means of synchronized operation with the intelligent wall switch such that both the switch and end device enter charge mode at the same time or the like. In one embodiment, an intelligent grid shifting lighting system may be developed using an intelligent wall switch and one or more lighting devices with a rechargeable integrated power source, charging circuitry, switch sense functionality and a light source that may be powered by either the external power input or the integrated power source. In such an embodiment, the intelligent wall switch may be programmed to use time of day to enter charging mode when the lighting device may not be used, for example during night hours when there is no occupancy in an office space. The lighting devices may detect that the intelligent wall switch is in charge mode and also enter charge mode. As such, the lighting devices use the external power source to charge the integrated power source if needed and do not illuminate the light source. The intelligent wall switch may have user control, for example an on/off switch, such that a user may turn the lighting devices on and off as desired. If a user turns the lights on while in charging mode, the lighting devices may detect the change in switch state and illuminate the light source. In embodiments, the lighting devices have a time of day clock and enter charging mode approximately at the same time as the intelligent wall switch. The intelligent wall switch may be any type of switch or controlling device used to control an electrical or lighting circuit such as but not limited to toggle switches, dimmer switches, three way or multi-way switches, timer controlled switches, motion sensor switches, push button or touch switches, paddle switches, solid state switches, slide switches, rotary switches, control panels, lighting control systems, dedicated charge mode devices and the like. The intelligent grid shifting system may be used for grid shifting for energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power or any other use of a hybrid power system mentioned herein.

In an illustrative embodiment, a method for implementing grid shifting that allows a sharing of the load among one or more power sources is described for use in a Power Sharing Approach for Grid Shifting 100. With reference to FIG. 1, illustrated is a block diagram view of an embodiment of a Power Sharing Approach for Grid Shifting 100. In the illustrated embodiment, the Power Sharing Approach for Grid Shifting 100 includes one or more power sources 110, a power sensing mechanism 120, power control 130, a sharing circuit 140, end devices 150 and a processor 160. The Power Sharing Approach for Grid Shifting 100 may be implemented inside a device, may be a module that may integrate into a device, may be implemented in a device that controls an electrical circuit where multiple end devices are controlled, may be implemented across multiple electrical circuits (e.g., at a breaker box or at the building level) etc. The Power Sharing Approach for Grid Shifting 100 may be implemented by monitoring the amount of power consumed from one or more power sources 110 via a power sensing mechanism 120 and a processor 160, then the processor 160 may configure a power control 130 mechanism to adjust the amount of power supplied from different sources. The result, using a sharing circuit 140, is the ability to control how much power comes from each source to power end devices 150 connected to the grid shifting solution. In some embodiments, the processor 160 may be programmed with an algorithm to determine the amount of sharing based on time of day, measurements of power consumed from different power sources, measurements of environmental variables such as battery capacity level or any other purpose that may benefit from the sharing of load by more than one power source. In embodiments, the processor 160 may be configured via an external communication mechanism to configure or program the processor 160 to implement a power sharing algorithm. In one embodiment, the power sensing mechanism 120 may use sense resistors and a microcontroller with the ability to measure the amount of current through the sense resistors. The microcontroller may then use pulse width modulation or similar to implement a mechanism of power control to adjust the draw from the power sources based on the desired amount of sharing between the power sources. In one embodiment targeting LED lighting applications, two power sources may be an external power source such as AC power from the line and an integrated power source such as a rechargeable battery. In such a case, the LED lighting device may contain two LED drivers, one to drive the LEDs from line power and one to drive the LEDs from the integrated power source. The light source is the end device 150. The power control 130 mechanism may be the ability to PWM control each of the LED drivers such that the percentage of power drawn from each power source to provide power to the light source may be controlled by using PWM similar to how it is used for dimming purposes but in this case the dimming of the two power sources allows the processor 160 to control the amount of power from each source. The sharing circuit 140 may be a simple diode OR of the two power sources after the power control 130 mechanism and after the output of the LED drivers. In embodiments, the Power Sharing Approach for Grid Shifting 100 may be implemented with multiple end devices powered by the output. By way of an example, an electrical circuit controlled by a 15 amp circuit breaker may have a device using the Power Sharing Approach for Grid Shifting 100 method to provide grid shifting among more than one power source to the electrical circuit. In the example, the two power sources may be AC power after the 15 amp circuit breaker and a local backup power device such as an inverter with an integrated battery. The power sharing approach may apply to AC power as it is distributed on the electrical circuit and some of the load typically supplied by AC power may be supplied by the inverter with an integrated battery. Any end devices on the circuit may benefit from the sharing approach. In embodiments, the Power Sharing Approach for Grid Shifting 100 may be used wherein an external command may be received from a demand response server or lighting control system by the processor 160 such that the processor 160 may control the amount of power consumed from the two power sources in response to the external command received. By way of an example, an LED light source may be driven by a constant current driver from grid power and a constant current driver from an energy storage device. The processor 160 may configure a power control 130 mechanism to adjust the amount of power supplied from each of the power sources and in some cases maintain a light intensity level while shifting some or all of the power consumption to the energy storage device.

In embodiments, a Battery Backed LED Driver may be constructed. FIG. 2 shows a block diagram of the Battery Backed LED Driver 200 that may use the external power source or integrated power source if the external power source is not available. The Battery Backed LED Driver 200 may include an external power input 210, an AC/DC converter 220, battery charger circuitry 230, a power source selection circuit 240, a step up LED driver 250, an integrated power source 260 and an external control input 270. A Battery Backed LED Driver 200 may be designed with power source selection circuit 240 such that when external power is applied, the external power input 210 supplies power to the light source. When the external power is no longer present the power source selection circuit 240 may automatically switch such that the integrated power source 260 may supply power to the light source. In the illustrative embodiment, the light source may be driven by the step up LED driver 250 whether the power source is the external power input 210 or the integrated power source 260. In the illustrative embodiment, the power selection circuit 240 consists of diode and a FET to allow for the automatic selection of the power source into the step up LED driver 250 such that when power is supplied by the external input, the battery is disconnected from the step up LED driver 250 and when power is not supplied at the external input the FET connects the integrated power source 260 to the step up LED driver 250. In embodiments the switching circuitry may consist of a relay, solid state switch, discrete circuitry and the like such that the desired power source may be supplied. It is to be appreciated that several methods of selecting and switching the power source will be readily apparent to those skilled in the art. In the illustrated embodiment, the step up LED driver 250 is a Linear Technology LT3755 step up LED driver 250. It is to be appreciated that any type of step up DC/DC converter and/or LED constant current driver circuit may be used to supply power with the desired drive characteristics. It is to be appreciated that any alternate LED driver may be used and that driver may be a step up driver, a step down driver, a buck boost driver or the like.

In the illustrated embodiment, the embedded battery supply 260 is a dual cell Li-Ion battery pack. The integrated power source 260 may be any rechargeable battery type mentioned herein. In embodiments, the integrated power source 260 may be non-rechargeable such as one or more alkaline batteries. In other embodiments, the integrated power source 260 may be a capacitor, super capacitor, fuel cell etc. In the illustrative embodiment, the dual cell Li-Ion battery pack is charged with dual cell Li-Ion charging circuit based on the Microchip MCP73213 battery charger. It is to be appreciated that any type of battery charger circuit may be used to charge the desired type rechargeable battery used as the integrated power source 260. In the illustrated embodiment, the AC/DC converter 220 may be any AC/DC converter circuit that meets the requirements of the application. In embodiments, the Battery Backed LED Driver 200 may be designed into a housing to allow it to be integrated into LED lighting devices or used external to LED lighting devices. The housing may have a mounting mechanism to allow it to be physically mounted inside or outside of an LED lighting device. Thus a Battery Backed LED Driver Module may be designed into a singular housing to provide LED drive and battery backup capabilities with the functionality to select the power source and drive the LED light source integrated into the module. In embodiments of a lighting system capable of reducing the power consumption but maintaining a light intensity level, the Battery Backed LED Driver 200 may be used wherein an external command may be received from a demand response server or lighting control system such that the driver may control the amount of power consumed from the two power sources in response to the external command received. By way of an example, an LED light source may be driven by the Battery Backed LED Driver 200 wherein a constant current driver from grid power and a constant current driver from an energy storage device may provide power to the LED light source. The Battery Backed LED Driver 200 may configure a mechanism to adjust the amount of power supplied from each of the power sources and in some cases maintain a light intensity level while shifting some or all of the power consumption to the energy storage device.

The external control input 270 may receive an input or detect a condition that allows the Battery Backed LED Driver 200 to make a decision on which power source to use to power the light source. In the illustrated embodiment, the external control input 270 may receive an input or detect the condition and control the shutdown input to the LT3755 such that the LT3755 will not drive the output. The external control input may enable or disable the integrated power source 260 to supply power using FETs, relays or any other type of control that would allow the external control input 270 to enable or disable integrated power source 240 and/or the external power input 210 from supplying power. The switching devices may be at any position in the circuit to implement the required switching function. In embodiments, power may be shared such that intelligence in the Battery Backed LED Driver 200 may control the power sources such that they both supply some amount of power. The Battery Backed LED Driver 200 may contain a battery level detector to provide an indication of the capacity remaining in the integrated power source 260. By way of an example, an external LED may be driven when the battery level voltage is below a threshold that may indicate a low battery level. The external LED may be mounted in the ceiling to provide a visual indication of the battery capacity level or if the battery is being charged. An indication of the battery capacity level or charging may be provided in any manner described herein.

In embodiments of a battery embedded module for use in retrofit LED fixtures, the battery embedded module may be used for grid shifting applications. In some embodiments, the Grid Shifting Battery Embedded LED Driver Module may contain elements of the Power Sharing Approach for Grid Shifting 100 and the Battery Backed LED Driver 200 or the like to allow the integrated power source to be used for grid shifting for energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power or any other use of a hybrid power system mentioned herein. In embodiments, intelligence may be designed into the module to implement a grid shifting algorithm to optimize the use of the device in a retrofit LED fixture.

In one use case, a peak shedding/grid shifting module may be designed that allows grid shifting to occur regularly when battery capacity is available to support grid shifting to achieve cost savings however at certain times when a peak in power usage is expected, for example in the summer months, the module may provide a peak shedding function. In some uses, the module may be integrated into a lighting device to provide this functionality. In other uses, the module may be integrated into any electrical device that may benefit from the peak shedding/grid shifting operation of the module. The module may have intelligence integrated into it to allow the device to hold reserve capacity to guarantee that capacity will be available for the required function. By way of an example, the module may allow grid shifting only down to fifty percent capacity of the integrated power source so that if peak shedding is required, the module may be able to provide that function for a minimum period of time. The module may have similar functionality to the automatic grid shifting wireless light bulb and peak shedding module mentioned herein. It is to be appreciated that grid shifting may be optimized for cost savings and energy efficiency and peak shedding may be optimized for reducing power consumption during peak times.

In embodiments targeting peak shedding, a peak monitoring device may be developed to communicate with devices capable of peak shedding to allow a central detection of a peak in power usage and subsequently control the peak shedding devices to transition power usage to integrated power sources to reduce power consumption during the peak times. When the peak in power usage is over, the peak monitoring device may communicate with the peak shedding devices to transition power back to the external power source. In some embodiments, the peak monitoring device may be electrically and physically connected to the monitored electrical interface. In embodiments, the peak monitoring device may be a current loop to detect the flow of energy on power lines without the need for a direct electrical or physical connection. The method of communication may be wired or wireless and a network of peak shedding devices may allow communication to the devices in a store and forward architecture. Communication between the peak monitoring device and peak shedding devices may be bidirectional such that the peak monitoring device may receive acknowledgements, status, alarms and the like from the peak shedding devices. By way of an example, a peak monitoring device may be attached to the circuit breaker box in a building such that it may monitor power usage at the circuit breaker box. In such a case, the peak monitoring device may be programmed with peak levels such that when it detects a peak level of power usage, the peak monitoring device may communicate control to the peak shedding devices to transition some amount of power to the integrated power source. The communication may include the amount of power to transition to the integrated power source such that the peak monitoring device may control the reduction in load. In another example, the peak shedding devices are lighting devices with integrated power sources. The peak monitoring device may detect a peak in power usage and send a command to the peak shedding lighting devices to move a certain amount of power from the external power input to the integrated power source. One advantage is that the light intensity of the lighting devices does not change but the power consumed from the external power input (and from the source of the power where the peak monitoring device is monitoring) will be reduced during the peak time.

In embodiments of wireless light bulbs and controlling devices using an AC power input, the wireless light bulbs may use the frequency of the AC power input for clocking purposes such that several wireless light bulbs and controlling devices may be synchronized in counting such that local clocks on individual devices may be in sync. By way of an example, an intelligent wall switch that controls one or more wireless light bulbs on the same circuit may use a timer or time of day to determine when to enter charging mode. In embodiments where the wireless light bulbs may use a timer or time of day to enter charging mode, maintaining a count synchronized by the frequency of the AC power input that all devices on the circuit are able to detect provides a mechanism to allow the counts to remain synchronized while the AC power input is applied. In some embodiments, the wireless light bulbs may lock to the frequency provided by the AC power input. In such a case, when AC power is turned off to the wireless light bulbs, they may continue to count based on the last detected frequency. There may be drift during the time that the wireless light bulb begins to count in the absence of the synchronizing frequency however the wireless light bulbs and controlling devices may be able to account for the drift and compensate for it. There may be a method independent of the frequency of the AC power input to synchronize the intelligent wall switch and wireless light bulbs at some point in time thereafter the controlling devices and wireless light bulbs may use the frequency of the power to remain in sync.

In embodiments of battery backed LED lighting, a traffic signal may be constructed containing an internal battery backup, charging circuitry, connection to external power for normal operation and charging and the intelligence to switch over to battery backup and continue operation in the event of a power outage. In some embodiments, the battery backed LED traffic signal may continue operation as prior to the outage for example by continuing cycling between red, yellow and green based on the timing previously used. In these embodiments, the battery backed LED traffic light may learn the operational timing of the traffic light in terms of timing. In some embodiments, a traffic light may communicate with other traffic lights using wired or wireless communication to allow the timing of the lights to remain in sync during the power outage. In embodiments, the battery backed LED traffic signal may enter a flashing operation such that upon a detected power outage, power for the traffic signal may be transitioned to the battery backup and the signal may flash the yellow light or red light. In these embodiments, the battery backed LED traffic signal may be programmable so the operation of the flashing light may be programmed with characteristics such as flashing color, duration of on and off time, light intensity of the light and the like. In the embodiment where the yellow light or red light are flashing, a battery embedded in the battery backed LED traffic signal allows for the traffic signal to operate without control received from a controller cabinet. In some embodiments, the battery backed LED traffic signal may be pre-programmed with a number of operational scenarios that an end user may select via a user interface to produce the desired operation.

In embodiments of battery embedded LED traffic signals, the traffic signal may use the embedded battery for grid shifting for cost savings, peak shedding, demand response, load leveling etc in addition to providing a battery backup for power outage situations. In such a case, the battery embedded LED traffic signals may be designed to store and use power from the embedded power source. The functionality may be pre-programmed, factory set, designed in a custom electrical circuit or the like to respond to sensors on the traffic light and a pre-programmed algorithm to implement the grid shifting function. In some embodiments, the grid shifting function is based on an intelligent program internally that may use a real time clock, sensors or a communication interface to perform grid shifting. The intelligent program that uses a real time clock may be set by the user such that the intelligent program may use time of day or a calendar to perform the grid shifting functionality. The grid shifting function may be used for cost savings, energy efficiency, convenience and safety/security. A battery embedded LED traffic signal may have switches, dials, knobs, USB connector etc on or inside the traffic signal housing to set time of day or sensor thresholds such that a user may be able to control how the intelligent program manages grid shifting. Once set, the battery embedded LED traffic signal may act based on those settings and/or the pre-programmed or designed function. The settings may be changed on occasion by the user. A battery embedded LED traffic signal may allow battery backup in power outage situation, cost savings by storing energy when the rates are cheap then using the stored energy when it is expensive and peak shedding functionality. In some embodiments of battery embedded LED traffic signals, an energy harvesting power source may be included, such as solar cells, capturing radio frequency energy and the like to allow an additional power source to power the traffic light or recharge the embedded battery. In these embodiments, the energy harvesting method may be directly integrated into the housing of the traffic light. By way of an example, solar cells may be installed on the top of the housing of the traffic light. In another example, an antenna and circuit to capture radio frequency energy may be integrated into the traffic light. In embodiments, an external energy harvesting method may be used. In the example of solar cells, a larger solar panel may be installed and positioned to optimize energy harvesting and a cable over to the battery embedded LED traffic light may allow the power consumption of the traffic light to be partially supplied by the solar panel or the solar panel may be used to charge the embedded battery.

In embodiments, the present invention may provide for a power outage lighting management within an environment, comprising a lighting device adapted to detect a power outage condition and power the lighting device by an internal power source. In embodiments, the lighting device may include a light source that is powered selectively by either the internal power source or an external power source. In response to detecting, the lighting device including the LED light source that is powered by the internal power source may regulate a light intensity of the LED light source in accordance with the power outage indication data, such as the light intensity as a dimmed light condition, the light intensity as a full brightness light condition, and the like.

In embodiments, the present invention may provide for a system of power management and control of an electrical facility, comprising the electrical facility that includes an electrical device, an internal power source, a connection to an external power source through an external power control device, a power source management facility, and a switch sense facility that senses the power control state of the external power control device, wherein the power source management facility controls the source of power being delivered to the electrical device based on the switch sense facility detecting at least one of the power control state of the external power control device and the presence of power being received from the external power control device. In embodiments, the electrical facility is a lighting facility and the electrical device is a lighting source, and where the lighting source may be an LED lighting source. The internal power source, the power source management facility, and the switch sense facility may be external to the lighting facility, and the like. The internal power source, the power source management facility, and the switch sense facility may be external to the electrical device. The power control state may be determined through a sensing of current in an electrical signal sent by the switch sense facility onto the input power connection. Sensing of current may utilize taking multiple samples, averaging, statistical determination, and the like, to determine measured current sense. The power control state may be determined through a sensing of reflections from an incident electrical pulse sent by the switch sense facility onto the input power connection. There may be an electrical coupling between the input power connection and the switch sense facility. The power source management facility may place the internal power source in a charge mode when there is power being received by the external power control device. The power source management facility may power the lighting source from the internal power source when the switch sense facility senses that the power control state of the external power control device is on and that there is no power being received by the lighting facility. The external power control device may be a device that is used to apply power to an electrical circuit. The external power control device may be a device that is used to apply power to a lighting circuit. The power control state may be an open switch or a closed switch. The power control state may be a partially on state from a dimmer device. The power control state may be determined from a threshold value, where the threshold value is predetermined, learned by the switch sense facility, and the like. The learning may be based on an electrical signal provided on the input power connection. The external power source may be AC power, DC power, and the like. The switch sense facility may sense the presence of power being received prior to the external power control device through a power sensing circuit in the external power control device. The power sensing circuit may insert impedance on the circuit that the switch sense facility may detect. The power source management facility may change the source of the power being used by the lighting facility based on the state of the power sensing circuit detected by the switch sense facility. The lighting facility may provide protection circuitry to protect against at least one of electrical transients and surges, where the protection may be to protect the switch sense facility.

In embodiments, the present invention may provide for an uninterruptable lighting source, including an uninterruptable lighting fixture containing an LED lighting source and a control facility for manipulating light output of the LED lighting source and selecting which source of power to use, wherein the uninterruptable lighting fixture provides the LED lighting source in response to a disruption of an external power source, and a rechargeable energy storage device capable of supplying power to the uninterruptable lighting fixture independent of the external power source, where recharging is provided to the uninterruptable lighting fixture at a time when the external power source is available. In embodiments, the external power source may be at least one of an AC and DC external power source. The uninterruptable lighting source may be designed to be a retrofit uninterruptable lighting fixture that replaces an existing lighting fixture. The rechargeable energy storage device and control facility may be integrated with the LED lighting source. The rechargeable energy storage device and control facility may be housed externally to the LED lighting source. The rechargeable energy storage device may be at least one of a battery, fuel cell, and super capacitor. The rechargeable energy storage device may be charged from the external power source. The rechargeable energy storage device may be charged from a constant current drive to the LED light source. The uninterruptable lighting facility may provide illumination based upon a setting of a switch. The switch setting may be sensed by the control facility through at least one of electrical impedance and AC power at the switch. The control facility may receive input through an input component in selecting which source of power to use. The input component may be a switch sense input component that senses at least one of a switch position and the presence of switch power for an external switching facility providing the external power source. The switch position of the external switching facility may be through electrical impedance sensing of the switch. The input component may be an RF input receiving component that receives commands from an external power outage detector. The input component may include a wireless interface from a power sensing facility that may detect a disruption of power. The wireless interface may be a connection to a network. The indication of power outage may be detected over the wired interface. At least one of an internal timer and a time of day clock may control the manipulating. The uninterruptable lighting fixture may include a sensor input device for detecting an environmental condition. The sensor may be a light sensor sensing a level of ambient light. The sensor may be a motion sensor sensing motion. The control facility may control when the rechargeable energy storage device is charging. The manipulating may be switching on the light output, changing an illumination level of the light output, flashing the light output, changing color content of the light output, and the like. The energy storage device may be capable of supplying the source of power for the lighting fixture to provide power management. Power management may be due to external power being interrupted, to improve energy efficiency, to provide cost savings, to reduce energy demand, and the like. The energy demand may be a peak energy demand, at predetermined times, at a time when new energy demand may be required at an energy provider, and the like. The control facility may utilize a control input from an input device, internal timer, internal clock, internal program to manage the power usage, and the like. The management of power usage may be through selection of the power source. The management of power usage may be through control of when a power source is charging. The management of power usage may be through the amount of load shared by the power sources.

In embodiments, the present invention may provide for power management of a lighting source, including providing a lighting facility, where the lighting facility may include the lighting source, an input device, an internal control facility, an energy storage device, a connection to external power, and the like. Sharing power usage between the external power and the energy storage device may be controlled by the internal control facility, where the internal control facility includes an intelligence capability that may utilize a resident program and information received through the input device in the sharing of power usage. In embodiments, the resident program may be stored on memory running on a processor in the internal control facility. Information received through the input device for power sharing may be processed in the internal control facility through dedicated circuitry. The lighting source may be an LED light. The external power may be external AC power. The external power may be external DC power. Sharing of power may be a partial sharing of power between the external power and the energy storage device, where both the external power and the energy storage device as a result of the information received are now supplying power. The input device may receive a program control input to alter the program, input from a remote control, input from a wireless network, input from a sensor, and the like. The input device may receive an external control signal, where a utility company, a networked software application, and the like may generate the external control signal. The external control signal may be communicated from at least one of wirelessly from a network, through the power lines, through a wired network connection, and the like. The energy storage device may be capable of supplying the source of power for the lighting facility to provide power management, where power management may be due to external power being interrupted, to improve energy efficiency, to provide cost savings, to reduce energy demand, and the like. The energy demand may be a peak energy demand, at predetermined times, at a time when new energy demand is required at an energy provider. The internal control facility may utilize a control input from an input device, internal timer, internal clock, internal program, and the like to manage the power usage. The management of power usage may be through selection of the power source, through control of when a power source is charging, through the amount of load shared by the power sources, and the like.

In systems containing devices with an embedded power source on an electrical circuit such as grid shifting systems or battery backup systems, an intelligent charging device may be designed to apply power to the electrical circuit for the purpose of charging the embedded power sources. In such a case, the grid shifting or battery backed up devices may be able to detect when the intelligent charging device is in charging mode and when the operation is based on the controlling devices passing power through onto the electrical circuit for normal operation. In some embodiments, switch sense functionality in end devices may be used to determine whether the applied power is for normal operation or for charging mode. By way of an example, a wall switch controlling an electrical circuit may contain a relay in parallel with the controlling device such that intelligence in the wall switch may apply power to the electrical circuit independent of the state of the controlling device (e.g., in parallel to the controlling device). In the example, the intelligence in the wall switch may use a timer or time of day clock to allow power to be applied to one or more electrical devices for the purposes of charging the battery based on time of day or some other timing mechanism when the user does not intend to power the electrical devices from the external power source for normal operation. In some embodiments, the intelligent charging device may use one or more sensors to determine whether to enter charge mode. By way of an example, a motion sensor may detect occupancy in a room. When no motion has been detected for a period of time, the intelligent charging device may enter charge mode. If motion is detected, the intelligent charging device may exit charge mode and the electrical devices may enter normal operation. In this example, if the electrical devices are lighting devices or lighting fixtures, there may be multiple levels of illumination such that when in charge mode, the illumination level is at a lower level where some of the power delivered may be diverted to charge the embedded power source however when the lights enter normal operation (for example, when motion is detected) the lights set the illumination level to a higher level. In embodiments, the intelligent charging device may close a switch automatically at certain times when the electrical devices may be charging. In some embodiments, the intelligent charging device may monitor current to the circuit to determine if the electrical devices are charging or the rate at which they are charging. In some embodiments, the intelligent charging device may use wired or wireless communication to the electrical devices to communicate whether it is in charging mode or normal operation mode. By way of an example, the intelligent charging device may use a power line communication method to communicate the mode of operation to end devices on an electrical circuit. In some embodiment, the intelligent charging device may provide a mechanism that may be detected by a switch sense circuit such that the switch sense circuit may know that the intelligent charging device is in charging mode and as such not enter its normal operating mode but rather enter a charging mode. By way of an example, the intelligent charging device may insert some impedance based on the charge mode approach that the switch sense circuit may detect as a third state that indicates charging mode. In embodiments, the intelligent charging device may periodically switch to charging mode when it detects that the wall switch is turned to the off position. The intelligent charging device may learn over time typical times when the intelligent charging device may be in the off position and create a schedule of charging times. In embodiments, the functionality may be implemented by a controlling device and integrated circuitry or a module into the controlling device to implement the same functionality as the intelligent charging device. In such embodiments, an existing controlling device may be retrofit with the integrated circuitry or module to allow it to provide the same or similar functionality as the intelligent charging device. In one illustrative example, a grid shifting lighting system may be developed controlled by an intelligent charging device such that batteries embedded in the lights may be charged during times when the user intended the lights to be turned off. In this example, the intelligent charging device may charge the embedded batteries by applying power to the circuit but the lights may be placed in charging mode by wired communication, wireless communication or a switch sensing mechanism and remain off during charging mode.

In embodiments of grid shifting systems, an intelligent grid shifting controller may control charging of embedded power sources and control the use of external and embedded power sources. In embodiments, the intelligent grid shifting controller may contain all of the functionality of the intelligent charging device but may communicate to the end devices the use of the external and embedded power sources. The intelligent grid shifting controller may communicate to the grid shifting end devices when to use the external power source, when to use the embedded power source and when to use both power sources sharing the load. The method of communication may be by wired connection over a power distribution network, for example on the AC power lines (X10, INSTEON, Broadband over Power Lines, proprietary communication scheme etc), or wirelessly through a wireless interface (dedicated RF communication link, ZIGBEE, WIFI, ENOCEAN, BLUETOOTH etc).

In embodiments of battery backed ballasts for fluorescent lighting or battery backed LED driver modules, a ballast or driver module may contain a light source or be able to drive a separate light source in the event that a disruption in power is detected. In these embodiments, the light source may be embedded on the housing of the ballast or driver module or the light source may be in a separate housing that may mount in a location to illuminate an area during a disruption of power. In some embodiments, during a disruption of power the ballast or driver module may drive both the separate light source and the primary light source deriving power from the embedded battery. In some embodiments, during a disruption of power the ballast or driver module may drive only the separate light source deriving power from the embedded battery. By way of an example, a battery backed ballast for fluorescent lighting may mount above a drop ceiling and a separate light source may be mounted in a location nearby to illuminate an area during a disruption in power. The battery backed ballast may have a connection to the separate light source to power it from the embedded battery during a power disruption. In such a use case, a battery backed ballast may power both fluorescent lighting and a separate emergency light during an emergency. In an alternate use case, a battery backed ballast may power only the separate emergency light. In this use case, a separate emergency light may have lower power requirements and thus may require a smaller battery reducing the size and cost. In another use case a light source built into the housing for the ballast or driver module may allow the ballast or driver module to act as the emergency light source. By way of an example, the housing may have an LED light source and a method to mount the housing to a drop ceiling such that the housing and LED light source may be positioned to illuminate an area during a disruption of power.

In embodiments of grid shifting systems, the amount of power to shift to an internal power source may be communicated to an end device using a triac or similar device to create a chopped waveform such that the amount of power that comes from the external power source and the amount of power supplied by an internal power source may be provided in proportion to the chopped waveform. In such embodiments, a controlling device may contain a triac or similar device and may be configured to control the waveform such that an end device powered on the circuit may process the waveform and control the amount of power delivered to an end device based on the input power waveform. By way of an example, a triac based dimmer switch that is used to typically control the light intensity level of a light source may be used to control the amount of power shifted to the internal power source. In such an example, a variable resistor may be used to control how much power is drawn from the line. In some embodiments, the device may use the chopped waveform to manage the amount of power supplied by the external and internal power sources based on the external power waveform. In embodiments, the controller device may use any known method to manipulate or modulate the waveform to communicate the amount of power to shift to the internal power supply. In some embodiments, an intelligent triac based grid shifting controller with the capability of chopping the waveform may be used to control the amount of power shifted to the internal power source. The intelligent triac based grid shifting controller may receive communication from an external device to configure or program the controller. The method of communication may be by wired connection over a power distribution network, for example on the AC power lines (X10, INSTEON, Broadband over Power Lines, proprietary communication scheme etc), or wirelessly through a wireless interface (dedicated RF communication link, ZIGBEE, WIFI, ENOCEAN, BLUETOOTH etc). In some embodiments, the intelligent triac based grid shifting controller may allow direct input through a keypad, LCD screen, computer connected through a USB interface etc and may be programmed to implement the communication to the end device to perform grid shifting. In embodiments, the functionality may be pre-programmed, factory set, designed in a custom electrical circuit or the like to respond to sensor inputs and a pre-programmed algorithm to implement the grid shifting function. The sensors may include a light sensor, motion sensor, an atomic clock or time receiver, temperature sensor or any other sensor mentioned herein that may allow the grid shifting function to meet the requirements of an application. In some embodiments, the grid shifting function is performed based on an intelligent program internally. The intelligent program may contain a real time clock that may be set by the user such that the intelligent program may use time of day or a calendar to perform the grid shifting functionality. The grid shifting function may be used for cost savings, energy efficiency, convenience, safety/security and the like. The controller may have switches, dials, knobs etc to set time of day or sensor thresholds such that a user may be able to control how the intelligent program manages the grid shifting. Once set, the controller may act based on those settings and/or the pre-programmed or designed function. The settings may be changed on occasion by the user. In embodiments where the external power source is a DC power source, a controlling device may use pulse width modulation, amplitude modulation and the like to communicate to a DC powered end device the amount of power to shift to an embedded power source. In an example of a triac controlled grid shifting system, the end device may be a lighting device with an internal power source and the controller may be a wall switch with a triac as well as some intelligence built in. The controller may be programmed to shift some amount of power to the internal power source during daytime hours for cost savings. In another lighting example, the controller may receive a command from an external device to implement a demand response function where the controller may chop the waveform and shift an amount of power delivered to the end device to the internal power source such that the amount of power drawn from the external power source may be reduced however the light intensity may be maintained because the difference in power consumed from the external power source may be transferred to the internal power source. In embodiments of a lighting devices capable of reducing the power consumption but maintaining a light intensity level, the device may be capable of detecting the chopped waveform created by a triac or similar device and adjust the amount of power consumed from each power source accordingly.

In an embodiment, a triac chopped waveform may indicate amount of power to transition to an internal power supply such as a rechargeable battery for grid shifting. A partial inverter grid shifting device may be designed that rebuilds an AC waveform from the triac chopped version such that a connected AC powered end device sees a clean AC waveform for its input power. Thus, the input to the partial inverter grid shifting device may be from no waveform to a full waveform with any chopped waveform in between however the partial inverter grid shifting device may use the internal rechargeable battery converted from DC to AC and combined with the input waveform to output a waveform similar to a full AC waveform. A partial inverter grid shifting system would allow a sharing of power between the external power supply and power stored in the rechargeable battery. In embodiments, the input waveform is a full AC waveform and the partial inverter grid shifting device combine the input from the input power supply and the internal power supply to shift some amount of power to the external device to be provided by the internal power supply. The amount of power supplied by the internal power source may lower the amount of power required from the input power source. In some embodiments, a method may be included in an inverter design that phase aligns the DC to AC waveform generated from the internal power source with the waveform of the input power source. By way of an example, embodiments may include a phase locked loop to synchronize with the input waveform such that the internally generated waveform may be generated to have a similar cycle as the input waveform. The phase alignment may be used to combine the two power sources to create the output power using relays, solid state switches and the like such that intelligence in the device may control one or more relays or switches to select the source of power. In one embodiment, the opening and closing of the relays to select the power source may be done in proportion to the amount of power that may be needed to be supplied from the input source or the internal power source. By way of an example, a processor may be programmed to provide 40% of the power from the internal power source. In this example, the processor may control a relay (for example a change over relay) such that the input power source may be selected by closing the relay on its connection to the external power path for 60% of the cycle and the internal power source may be connected to the external power path for 40% of the cycle. In an alternate example, the power source may be time division multiplexing between the two power sources on larger timer intervals. By way of an example, the input power source may be connected to the end device for 6 seconds then the internal power source may be connected to the end device for 4 seconds to implement a 60/40 sharing of power. In some embodiments, the input power source may be DC and in such a case the input power source and internal power supply may be combined using a method described herein (diode oring, PWM using FETs to or power sources, controlling solid state switches or relays etc) to shift power to the internal power supply.

In embodiments using a triac to control the amount of power to shift to an internal power source, the device may contain an AC/DC converter that may take a chopped waveform and convert it to DC power to provide a power source to charge rechargeable batteries in the device. Thus, a chopped waveform may be used to deliver some amount of power to a battery charging circuit to increase the charge of the rechargeable batteries. In some embodiments, the battery charging circuit may adjust the charge rate based on the input waveform.

In embodiment of grid shifting lighting devices or lighting devices dedicated to lighting, the lighting device may implement a sharing or shifting of power between the external power supply and power stored in an internal power source such as a rechargeable battery using a processor and relays, solid state switches and the like such that the processor may control one or more relays or switches to select the source of power to implement a time division multiplexing to set the amount of power used from the input power source and from the internal power source. In one embodiment, the opening and closing of the relays to select the power source may be done to in proportion to the amount of power that may be needed to be supplied from the input source or the internal power source. By way of an example, a processor may be programmed to provide 25% of the power from the internal power source for the purpose of reducing the demand from the grid during peak times but to maintain the same intensity level of the lighting devices. In this example, the processor may control a relay (for example a change over relay) such that the external power supply may be selected by closing the relay on its connection to the external power path for 75% of an interval of time and the internal power source may be connected to the external power path for 25% of an interval of time. In some examples, the power source may be time division multiplexing between the two power sources on larger intervals of time. By way of an example, the external power supply may be connected to illuminate the light source for 7.5 seconds then the internal power source may be connected to the end device for 2.5 seconds to implement a 75/25 sharing of power. In some embodiments, the external power supply may be AC power or DC power. In some embodiments, the external power source may be AC power but the power sharing may be implemented after an AC to DC conversion. In some embodiments, the external power supply and internal power supply may be combined using a method described herein (diode oring, PWM using FETs to or power sources, controlling solid state switches or relays etc) to shift power to the internal power supply. In some embodiments, the switchover between power sources may be in response to an outage of power or a low capacity level detected on one of the power supplies. By way of an example, the lighting device may detect a disruption in the external power supply and switch one or more relays to connect power from the internal power source to the load to be driven.

In some embodiments of grid shifting lighting devices, the device may monitor the amount of power consumed from the external power supply and adjust the amount of power supplied from the internal power supply to set the amount of power consumed from each source. In embodiments, an algorithm may be implemented to manage the power delivered by each of the power sources. By way of an example, an algorithm may be implemented to increase the amount of power supplied by the internal power source in steps monitoring the reduction in power from the external power supply to determine that the desired level of sharing of power between the two sources is achieved. In some examples, the algorithm may be such that a set power consumption level from the external power supply may be desired and power supplied from the internal power source may be adjusted until that level of power consumed from the external power supply is measured at the desired level.

In some embodiments of battery backed devices, a current measurement on an AC power line may be made using magnetic induction. A magnetic induction device including a large conductor with some number of turns may be wrapped around the conductor of the AC power source. The magnetic induction device may have a method to communicate the amount of power to devices such as emergency lighting devices, grid shifting devices and the like to allow those devices to make change state based on the measured power.

In an embodiment of a grid shifting lighting system, a system consisting of one or more lighting devices such as bulbs or fixtures and a grid shifting management device with an integrated power source that may power the one or more lighting devices. The grid shifting management device may have an external power supply such as an AC power source, a DC power source, a method of energy harvesting and the like for providing a source of power to the lighting devices or to recharge the integrated power source. The grid shifting management device may contain a processor for power management and shifting power between an external power supply and integrated power source for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein. In some embodiments, the integrate power source may not be in the grid shifting management device but may be distributed into the lighting devices where the grid shifting management device may perform power management and conversion functions with the external power supply and may communicate with the lighting devices to manage the grid shifting operation. In some embodiments, a processor in the grid shifting management device may manage grid shifting in the lighting devices. In embodiments, the lighting devices may contain a processor and when configured or programmed may implement grid shifting functions. In such embodiments, the grid shifting management device may provide the configuration or programming. The lighting devices may receive configuration or programming from another source such as an external control source such as a lighting control network. The lighting devices may have the ability to alter their configuration based on power consumption, sensor inputs or the like such that a change in the grid shifting function may be initiated by the lighting device in response to an input. By way of an example, a group of lighting devices may be DC powered lighting devices such as LED light fixtures. A grid shifting wall switch or controller may contain an AC/DC converter with the LED driver circuit capable of driving the light sources with the proper current and voltage as required by the light sources and fixtures. In embodiments, the grid shifting wall switch or controller may contain an AC/DC converter and supply a DC voltage to the light sources and fixtures which may contain the LED driver circuits for the light sources. It is to be appreciated that any type of light source and associated driver circuit may be used with the present invention. The grid shifting wall switch or controller may have an integrated or may have an external connection to a energy storage device such as a rechargeable battery that may be used for grid shifting purposes. The grid shifting wall switch or controller may be capable of managing power to use the energy storage device and external power source to implement grid shifting for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein. In another example, the lighting devices contain an energy storage device and may recharge or use the energy storage device for grid shifting purposes. In this example, the lighting devices may use a constant current of a certain level. The grid shifting wall switch or controller may initiate a shift to the energy storage device by reducing the amount of current supplied. A lighting device may detect the change and automatically begin to source the amount of current from its energy storage device to maintain the drive to the light source at the required level. The grid shifting wall switch or controller may change any characteristic of the power supplied to the lighting devices or may use any other method of communication mentioned herein to alter the management of power at the lighting devices to implement grid shifting. In embodiments, the end device may not be a lighting device but may be any type of electrical device that may benefit from the grid shifting function described herein.

An embodiment of grid shifting lighting devices or lighting devices with an emergency lighting capability may be a street light, street lamp or street light fixture with an internal power source such as a rechargeable battery that is capable of using the internal power source for grid shifting or emergency lighting purposes. The light source may be fluorescent, LED, HID, incandescent or any known lights source. In some embodiments, a replacement bulb that fits into a street light fixture may allow the fixture to be retrofit with grid shifting or emergency lighting functions. In some embodiments, the street light, street lamp or street light fixture that can grid shift may contain a grid tie inverter to return power to local devices or to the grid. In some embodiments, the street light, street lamp or street light fixture may have a connection to one or more external power sources, may have a connection to one or more energy harvesting power source such as solar, wind and the like and may have a connection to an external energy storage device in addition to or instead of an internal energy storage device. In some embodiments, the street light, street lamp or street light fixture may be controlled by RF or IR control, sensor control or any form of wireless control mentioned herein. By way of an example, a light sensor may be used for daylight harvesting for the purposes of changing the light intensity to conserve power based on the amount of ambient light detected. In another example, a motion sensor may be used to turn the light or change the light level if multiple light levels are implemented. In some embodiments, a coordinated lighting function may be implemented where any form of wireless control in one street light, street lamp or street light fixture may be propagated over a wired or wireless network to a group of street lights, street lamps or street light fixtures such that the group may be controlled in a coordinated manner. By way of an example, a motion sensor triggered in one street lamp may transmit a message to a group of street lamps to turn on even if the other members of the group do not directly detect the motion.

In an embodiment, a battery backed power supply module provide a backup power source and has a connection to AC power which may include wires before a controlling device (AC unswitched hot), after a controlling device (AC switched hot) and a return line (AC neutral) such that the module may be designed to plug into a relay control panel supplying power to lighting or electrical devices. When the battery backed power supply relay module detects that power is not present, the battery backed power supply relay module may power the devices on the circuit from the backup power source. In some embodiments, the battery backed power supply relay module may contain a switch sense circuit such that it may detect whether the controlling device intends for the devices on the circuit to be powered and may not apply power to the circuit. In embodiments, the battery backed power supply relay module may be dedicated to grid switching functions and as such may be used for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein.

In embodiments where emergency power may be provided during a disruption of power, an alternate form of control may be present to override automatic switchover or to allow another form of control in cases where it is not desirable to run off of the backup power source or where it is desirable to run off of the backup power source. By way of an example, a user may desire to turn the battery backed lighting off but does not want the lighting to switchover to battery power. In such an example, the user may have a remote control that may allow the user to control the power source, light source to illuminate, illumination level and the like.

Referring to FIG. 3, the present invention may provide a grid shifting electrical fixture 302 which may contain a processor 308 and a energy storage device 304 such as a battery and a connection to external power that is delivered through a grid shifting controller 310, where the processor 312 provides intelligent control of the grid shifting electrical fixture 302 for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein. In embodiments, processor 308 and processor 312 may include a microprocessor, a microcomputer, a digital logic circuit, an analog circuit, and the like. In the case where the processor contains a computing device, software for the computing device may fixed at the factory, updated though an external interface to the processor (e.g. though a wired or wireless connection), and the like. Processor 308 and/or processor 312 may make decisions on when and how to recharge the energy storage device, when the grid shifting electrical fixture 302 should shift or share power, why to shift or share power and how much power should be shifted or shared between the power sources. There may be a wired or wireless communication channel between processor 308 and processor 312 for control, status, programming, configuration and the like. In some embodiments, the grid shifting electrical fixture 302 may be a lighting fixture and as such the power source and light source may be managed by processor 308 and processor 312 to implement a grid shifting lighting fixture 302 containing the energy storage device 304. In some embodiments, the energy storage device and a controller or processor may be external to the grid shifting electrical fixture 302. In embodiments of a lighting system capable of reducing the power consumption but maintaining a light intensity level, the grid shifting controller may translate commands received from a utility company, lighting control system or demand response server to provide control to one or more grid shifting electrical fixtures 302 such that the lighting system reducing power consumption but maintaining the light intensity level consists of the fixture and the intermediate control device.

Referring to FIG. 4, the present invention may provide a grid shifting electrical fixture 402 which may contain a processor 408 and a connection to external power that is delivered through a grid shifting controller 410, where there may be an energy storage device 404 such as a battery and a processor 412 that provides intelligent control of the grid shifting electrical fixture 402 for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein. In embodiments, processor 408 and processor 412 may include a microprocessor, a microcomputer, a digital logic circuit, an analog circuit, and the like. In the case where the processor contains a computing device, software for the computing device may fixed at the factory, updated though an external interface to the processor (e.g. though a wired or wireless connection), and the like. Processor 408 and/or processor 412 may make decisions on when and how to recharge the energy storage device 404, when the grid shifting electrical fixture 402 should shift or share power, why to shift or share power and how much power should be shifted or shared between the power sources. There may be a wired or wireless communication channel between processor 408 and processor 412 for control, status, programming, configuration and the like. In some embodiments, the grid shifting electrical fixture 402 may be a lighting fixture and as such the power source and light source may be managed by processor 408 and processor 412 to implement a grid shifting lighting system with the grid shifting controller containing the energy storage device 404. In some embodiments, the energy storage device and a controller or processor may be external to the grid shifting controller 410. In some embodiments, the grid shifting electrical fixture 402 may not contain a processor and the grid shifting function may be implemented by the gird shifting controller 410 for one or more electrical fixture devices on the circuit managed by the controller.

Referring to FIG. 5, the present invention may provide for grid shifting for one or more lighting devices 502 and an external grid shifting controller 504, where the lighting device 502 may include a processor 508 with a lighting modes database 510, a grid shift controller 512, a power connection to external power 514, a light source 516, an internal power source such as a battery 518, grid shifting communication 522 and the like and where the external grid shifting controller 504 may include a power feed to the lighting fixture 524, grid shifting communication 526, a processor/controller 528, a connection to an external power supply 530, and the like. In embodiments, the lighting device 502 may use the battery for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein and as a result, determine whether to power the lighting device 502 using the power connection to external power 514, use the battery 518 or use some amount of power consumed from both sources. In embodiments, the processor 508 may include a microprocessor, a microcomputer, a digital logic circuit, an analog circuit, and the like. In the case where the processor contains a computing device, software for the computing device may fixed at the factory, updated though an external interface to the processor (e.g. though a wired or wireless connection), and the like. The processor 508 may have access to a lighting mode database 510 that may contain information pertaining to controlling the light source, power management to implement the grid shifting function, use of embedded sensors, wired or wireless interfaces and the like. In embodiments, the grid shift controller 512 may implement the sharing or shifting of power of the two power sources that may be combined using a method described herein (diode oring, PWM using FETs to or power sources, controlling solid state switches or relays etc). The power connection to external power 514 may be AC power, DC power or the like. The light source 516 may be fluorescent, LED, HID, incandescent or any known lights source. The light source 516 may be integrated into the same housing as the remaining components of the lighting device or may be removable and replaceable like a light bulb. Grid shift communication 522 may allow the external grid shifting controller 504 to communicate with the lighting device 508 to communicate grid shifting operation to the lighting devices, program or configure the processor 508 or grid shift controller 512, manage recharging the battery 518, gather status and the like. The external grid shifting controller 504 may allow for the control of the grid shifting system by allowing parameters of grid shifting to be entered such that the processor/controller 528 may make decisions on when and how to recharge the battery 518, when the lighting device 502 should shift or share power, why to shift or share power and how much power should be shifted or shared between the power sources. The decision may be based on programming, configuration, external control, sensor inputs, monitoring of power consumption and the like. By way of an example, the external grid shifting controller 504 may be a control panel that allows user input to program grid shifting operation. The processor/controller 528 may contain a real time clock that may allow the user to enter times of the day when the external grid shift controller may enter charge mode by communicating to the lighting devices 502 that they are entering a mode where the battery 518 is charged but the light source 516 is not illuminated. The user may program times of day and the percentage of power that will be supplied from the battery 518 source at those times of day such that the grid shift controller 512 may manage the two power sources to implement the sharing. The external grid shifting controller 504 may implement any of the grid shifting functions described herein.

In an embodiment, an autonomous grid shifting lighting device may be programmed or configured to implement grid shifting using its internal battery. Referring to FIG. 5, the present invention may provide for grid shifting of a lighting device 502 using the processor 508, lighting modes database 510 and grid shift controller 512 to manage the power connection to external power 514, light source 516 and battery 518 such that the lighting device may manage grid shifting operation based on its program. In such an embodiment, there is no external grid shifting controller and the operation of the lighting device is controlled by the components of the lighting device 502 as programmed or configured to operate.

Referring to FIG. 6, the present invention may provide for grid shifting for one or more lighting devices 602 and an external grid shifting controller 604, where the lighting device 602 may include a processor 608 with a lighting modes database 610, a controller 612, a power connection to external power 614, a light source 616, grid shifting communication 622 and the like and where the external grid shifting controller 604 may include a power feed to the lighting fixture 624, grid shifting communication 626, a processor/controller 628, a connection to an external power supply 630, an internal power source such as a battery 632 and the like. In embodiments, the external grid shifting controller 604 may use the battery for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein and as a result, determine whether to power one or more lighting devices 602 using the connection to an external power supply 630, using the battery 632 or using some amount of power consumed from both sources. In embodiments, the processor 608 may include a microprocessor, a microcomputer, a digital logic circuit, an analog circuit, and the like. In the case where the processor contains a computing device, software for the computing device may fixed at the factory, updated though an external interface to the processor (e.g. though a wired or wireless connection), and the like. The processor 608 may have access to a lighting mode database 610 that may contain information pertaining to controlling the light source, power management, use of embedded sensors, wired or wireless interfaces and the like. In embodiments, the controller 612 may implement power management of the light source 618 and power connection to external power 614. The power connection to external power 614 may be AC power, DC power or the like. The external grid shifting controller 604 may contain an AC/DC converter, DC/DC converter and the like to convert and condition the power for the lighting devices. The light source 616 may be fluorescent, LED, HID, incandescent or any known lights source. The light source 616 may be integrated into the same housing as the remaining components of the lighting device or may be removable and replaceable like a light bulb. Grid shift communication 622 may allow the external grid shifting controller 604 to communicate with the lighting device 608 to communicate grid shifting operation to the lighting devices, program or configure the processor 608 or controller 612, gather status and the like. The external grid shifting controller 604 may allow for the power management and control of the grid shifting system by allowing parameters of grid shifting to be entered such that the processor/controller 528 may make decisions on when and how to recharge the battery 632, when to shift or share power, why to shift or share power and how much power should be shifted or shared between the power sources. The decision may be based on programming, configuration, external control, sensor inputs, monitoring of power consumption and the like. By way of an example, the external grid shifting controller 604 may be a control panel that allows user input to program grid shifting operation. The processor/controller 628 may contain a real time clock that may allow the user to program times of day and the percentage of power that will be supplied from the battery 632 source at those times of day such that the processor/controller 628 may manage the two power sources to implement the sharing. The external grid shifting controller 604 may implement any of the grid shifting functions described herein.

Referring to FIG. 7A, the lighting device 702 may include an illumination source 704, housing 714, controller 708, timing facility 718, power sourcing facility 710, a first power source 712, a second power source 720, and the like. In embodiments, the first power source 712, second power source 720, or both, may be located as part of the housing 714 or outside the housing. Either or both of the power sources 712 or 720 may be any power source described herein, such as a battery, super capacitor, fuel cell, and the like. Either or both of the power sources 712 may be an external power source, such as the power grid, an external DC power source, and the like. For example, the first power source 712 may be a battery internal to the housing 714 and the second power source 720 may be the external power grid. In another example, the first power source 712 may be the external power grid and the second power source may be an external DC power source. Referring to FIG. 7B, In embodiments the lighting device 702 may include an illumination source mechanically associated with a housing 722; a timing facility which may be associated with the housing and in data communication with a controller 724; and where the controller may be mechanically associated with the housing and adapted to cause a power sourcing facility to select from two alternative power sources when powering the illumination source based on an input from the timing facility 728. In embodiments, the timing facility may utilize a calendar to determine times to select from the two alternative power sources. The timing facility may utilize a timing profile to determine times to select from the two alternative power sources. The timing facility may store times when selection is disabled. The timing facility may be a clock that is synchronized with a central clock. The timing facility may be a timer that counts to a predetermined period. The timing facility may utilize time of day. The controller may include a processor. The illumination source may be an LED. The lighting device may be an LED driver module and drive an LED illumination source. The lighting device may be a fluorescent lamp ballast and drive a fluorescent light source. The lighting device may be an inverter module driving a fluorescent lamp ballast and fluorescent light source. The lighting device may be a lighting fixture. The lighting fixture may include a housing that receives the illumination source. The lighting device may be an adapter that accepts the illumination source plugged into it. The step of selecting may involve switching between the two alternative power sources. The step of selecting may involve sharing power between the two alternative power sources simultaneously, such as where x percent of power is consumed from one of the alternative power sources and y percent of power is consumed from the other alternative power source.

Referring to FIG. 8A, the lighting device 802 may include an illumination source 804, a housing 814, a controller 808, a sensor facility 818, a power sourcing facility 810, a first power source 812, a second power source 820, and the like. In embodiments, the first power source 812, second power source 820, or both, may be located as part of the housing 814 or outside the housing. Either or both of the power sources 812 or 820 may be any power source described herein, such as a battery, super capacitor, fuel cell, and the like. Either or both of the power sources 812 may be an external power source, such as the power grid, an external DC power source, and the like. For example, the first power source 812 may be a battery internal to the housing 814 and the second power source 820 may be the external power grid. In another example, the first power source 812 may be the external power grid and the second power source may be an external DC power source. Referring to FIG. 8B, the lighting device 802 may provide an illumination source mechanically associated with a housing 822; a sensor facility mechanically associated with the housing and in data communication with a controller, the sensor facility adapted to assess a time of day through examination of lighting conditions proximate the housing 824; where the controller may be associated with the housing and adapted to cause a power sourcing facility to select from two alternative power sources when powering the illumination source based on an input from the sensing facility. In embodiments, the sensor facility may further comprise a motion detector that is in communication with the controller, the controller adapted to use data from the motion detector when determining which of the two alternative power sources to select. The motion detector may sense motion proximate to the housing. The sensor facility may further comprise a light sensor that is in communication with the controller, the controller adapted to use data from the light sensor when determining which of the two alternative power sources to select and how much power to draw from each source. The controller may include a processor. The illumination source may be an LED, where the lighting device may include an LED driver module. The lighting device may be a fluorescent lamp ballast and drive a fluorescent light source. The lighting device may be an inverter module driving a fluorescent lamp ballast and fluorescent light source. The lighting device may be a lighting fixture. The lighting fixture may include a housing that receives the illumination source. The lighting device may be an adapter that accepts the illumination source plugged into it. The step of selecting may involve switching between the two alternative power sources. The step of selecting may involve sharing power between the two alternative power sources simultaneously, such as where x percent of power is consumed from one of the alternative power sources and y percent of power is consumed from the other alternative power source.

Referring to FIG. 9A, the lighting device 902 may include a first power source 904, a second power source 908, an information source, such as to provide time of day information 914, and the like. In embodiments, the first power source 904, second power source 908, or both, may be located as part of the housing of the lighting device 902 or outside the housing. Either or both of the power sources 904 or 908 may be any power source described herein, such as a battery, super capacitor, fuel cell, and the like. Either or both of the power sources 904 or 908 may be an external power source, such as the power grid, an external DC power source, and the like. For example, the first power source 904 may be a battery internal to the housing and the second power source 908 may be the external power grid. In another example, the first power source 904 may be the external power grid and the second power source may be an external DC power source. In embodiments, the information source 912 may be located as a part of the lighting device 902, external to the lighting device, or some combination of internal and external. For example, the information source may provide the time of day to the lighting device 902 from a real time clock module inside the lighting device. In another example, the time of day clock may be maintained in the lighting device and synchronized or set to an external time source (e.g. NTP, an atomic clock, a user interface, and the like). In another example, the lighting device may not maintain the time however an external device maintaining the time may control operation of the lighting device based on time of day. Referring to FIG. 9B, the lighting device 902 may provide a method of shifting a lighting load off the grid 918 by connecting a lighting device to the grid 920; causing the lighting device to extract information from an information source proximate the lighting device, wherein the information is indicative of a time of day 922; causing the lighting device to select from two alternate power sources based on the information 924; and the like. In embodiments, a controller may perform the step of extracting information, where the controller may include a processor. The lighting device may include an LED lighting source. The LED lighting source may include an LED driver module. The lighting device may be a fluorescent lamp ballast and drive a fluorescent light source. The lighting device may be an inverter module driving a fluorescent lamp ballast and fluorescent light source. The lighting device may be a lighting fixture, where the lighting fixture includes a housing that receives the illumination source. The lighting device may be an adapter that accepts the illumination source plugged into it. The step of selecting may involve switching between the two alternative power sources. The step of selecting may involve sharing power between the two alternative power sources simultaneously, such as where x percent of power is consumed from one of the alternative power sources and y percent of power is consumed from the other alternative power source.

Referring to FIG. 10A, the lighting device 1002 may include an internal battery power source 1004, which may include a performance characteristic 1008 such as for battery capacity level; a connection to the power grid 1010; and the like. Referring to FIG. 10B, the lighting device 1002 may provide for shifting of a lighting load off the grid 1012 by connecting a lighting device to the grid 1014; causing the lighting device to monitor an internal battery power source for a performance characteristic 1018; causing the lighting device to select between the grid and the internal battery power source based on the performance characteristic 1020; and the like. In embodiments, the lighting device may include a controller for performing the steps of monitoring the internal battery and choosing between the grid and the internal battery, such as where the controller includes a processor. The lighting device may include an LED lighting source, and the LED lighting source may include an LED driver module. The lighting device may include a fluorescent lamp ballast. The lighting device may be an inverter module driving a fluorescent lamp ballast and fluorescent light source. The lighting device may be a lighting fixture. The lighting fixture may include a housing that receives the illumination source. The lighting device may be an adapter that accepts the illumination source plugged into it. The step of selecting may involve switching between the two alternative power sources. The step of selecting may involve sharing power between the two alternative power sources simultaneously, such as where x percent of power is consumed from one of the alternative power sources and y percent of power is consumed from the other alternative power source.

Referring to FIG. 11A, the lighting device 1102 may include a first power source 1104, a second power source 1108, predict an energy distribution grid demand parameter 1110, an environmental information source 1114, and the like. In embodiments, the first power source 1104, second power source 1108, or both, may be located as part of the housing of the lighting device 1102 or outside the housing. Either or both of the power sources 1104 1108 may be any power source described herein, such as a battery, super capacitor, fuel cell, and the like. Either or both of the power sources 1104 1108 may be an external power source, such as the power grid, an external DC power source, and the like. For example, the first power source 1104 may be a battery internal to the housing and the second power source 1108 may be the external power grid. In another example, the first power source 1104 may be the external power grid and the second power source may be an external DC power source. In embodiments, the information source 1114 may be located as a part of the lighting device 1102, external to the lighting device, or some combination of internal and external. The information source 1114 may be an environmental information source, a power input information source, and the like. For instance, the information source may enable the prediction or determination of an energy distribution grid parameter, such as to improve energy efficiency, provide cost savings, to reduce energy demand, and the like, such as when the energy demand is a peak energy demand, is at predetermined times, at a time when new energy demand is required at an energy provider, and the like. Referring to FIG. 11B, the lighting device 1102 may provide for shifting a portion of a lighting load off an energy distribution grid 1118 by electrically connecting a lighting device to the energy distribution grid 1120; causing the lighting device to interpret information obtained from an environmental information source, which may be proximate the lighting device, the interpretation adapted to predict an energy distribution grid demand parameter 1122; causing the lighting device to select from at least two different power sources based on the interpretation 1124; and the like. In embodiments, the lighting device may include a controller for performing the steps of interpreting the information and selecting between the at least two different power sources, where the controller may include a processor. The environmental information source may include an internal timer, a time of day clock, a calendar, an environmental sensor input device for detecting an environmental condition, and the like. The lighting device may be caused to assess a power viability factor associated with at least one of the at least two different power sources, and where the step of causing the lighting device to select from at least two different power sources may be based on the interpretation comprises causing the lighting device to select from the at least two different power sources based at least in part on the environmental information interpretation and at least in part on the power viability factor. The step of causing the lighting device to select from at least two different power sources based on the interpretation may involve switching between the two different power sources. The step of causing the lighting device to select from at least two different power sources based on the interpretation may involve simultaneously drawing power from the two different power sources, such as where x percent of power is consumed from one of the alternative power sources and y percent of power is consumed from the other alternative power source. The environmental sensor input device may be a light sensor sensing a level of ambient light. The environmental sensor input device may be a motion sensor sensing motion. A power sensor input device may also be included, such as where the power sensor input device measures the amount of power consumed from one or more of the power sources, the power sensor input device measures the capacity level of at least one of the two different power source, the power sensor input device allows for an estimation of the capacity level of at least one of the two different power sources, and the like. In some embodiments, the lighting device may not contain an environmental sensor input and instead rely on measurements of the power sensor input device to select from the at least two different power sources. The lighting device may include an LED lighting source, where the LED lighting source may include an LED driver module. The lighting device may further include a fluorescent lamp ballast. The lighting device may be an inverter module driving a fluorescent lamp ballast and fluorescent light source. The lighting device may be a lighting fixture, such as where lighting fixture includes a housing that receives the illumination source. The lighting device may be an adapter that accepts the illumination source plugged into it. The step of selecting may involve switching between the two alternative power sources. The step of selecting may involve sharing power between the two alternative power sources simultaneously, such as where x percent of power is consumed from one of the alternative power sources and y percent of power is consumed from the other alternative power source.

In embodiments, a regional grid shifting architecture may be created such that a power provider in a region may implement a peak shedding algorithm to reduce demand in the region by instructing end users to reduce demand by shifting power to the local power sources of the grid shifting lighting and electrical devices through the issuing of load control messages (e.g., communication with controlling facilities at the energy users) or through the use of time of day and calendar to schedule end users to shift some amount of power off the grid at scheduled times. The transmission utility that supplies one or more regions and the lighting or electrical devices at the end user facilities described herein may be deployed in each of those regions such that the load that is demanded from the grid is reduced through the power management techniques (e.g., load control messages, time of day scheduling, etc.). As a result, the power provider in a region may not need to bring any additional infrastructure on-line to meet peak demand.

In embodiments of grid shifting lighting devices, grid shifting electrical devices and grid shifting controllers, a wide area wireless network interface may be integrated into the grid shifting devices such that the wireless interface in the grid shifting devices may allow a power provider or intermediary to issue instructions over the wireless network to end devices and controllers to implement grid shifting. In such embodiments, a power provider may issue unicast, multicast or broadcast instructions to the grid shifting devices over the wireless network. The power provider may be able to reduce power consumption by issuing instructions over the wireless network to end devices and controllers to transition some of their power consumption to local power sources. The power provider may be able to implement peak shedding or other function to make use of local power sources implement in end devices without the need for power line communication or other methods that may require additional infrastructure and cost to implement. By way of an example, a 2.5G or 3G network may be used by a power provider when 2.5G or 3G network interfaces are integrated into a grid shifting device. A protocol may be developed to allow unidirectional or bidirectional communication between the power provider and end devices. In embodiments, the protocol may be implemented over the power lines to communicate with the grid shifting devices.

In embodiments of grid shifting lighting devices, a triac dimmable driver may be implemented where a control facility provides power management such that a battery driver circuit automatically makes up the difference of the power delivered to the light source from the amount of power that is detected that has been reduced in the triac chopped waveform. By way of an example, an LED light source may be driven by an oring of the external power source including a triac chopped waveform and an LED battery driver circuit. A control facility may manage the amount of power delivered by the LED battery driver circuit in response to the amount of power delivered by the external power source.

In an embodiment of a grid shifting lighting device, a light may be implemented that grid shifts to use power from a local energy storage device to allow users and workers to work through a rolling blackout, scheduled outage or unscheduled disruption in power. In some embodiments, the light may contain the switch sense functionality to automatically switch to the local energy storage device during the outage. In embodiments, the light may contain a time of day and calendar such that it may be programmed with a schedule of when to use the primary power source and when to use the local energy storage device. In embodiments, the light may contain a wireless receiver such that a user may use the remote control containing controls and a wireless transmitter to turn on, turn off or alter the light intensity of the light. In embodiments, the wireless receiver may be a wireless wide area network interface such as a 2.5G or 3G interface and a power provider may transmit a message in a geographical area when the rolling or scheduled blackout will happen and the light may automatically switch over to the local power source for the duration of the outage. In embodiments, the lighting device may be a fixture, bulb, retrofit fixture, fluorescent lamp or light fixture, LED fixture or the like. In embodiments, a grid shifting production/manufacturing battery module may be used to provide grid shifting functionality to any lighting device by providing the grid shifting capability in line with external power to the lighting device. The external power may be AC or DC. By way of an example, a grid shifting production/manufacturing battery inverter module may be designed to pass AC power when it is available but upon an outage or upon user control, switchover to power the lighting device from the battery inverter circuit.

In an embodiment of a grid shifting lighting system, a group of DC powered lighting devices and a grid shifting controller may be deployed to provide a lighting solution to an area with poor power distribution (e.g., without access to or isolated from a power provider, receiving unreliable power from a power provider or the like). In the embodiment, a power source such as a battery, a generator, an energy harvesting power source (solar, wind etc), an AC/DC converter etc. located proximate or inside a grid shifting controller may be deployed as part of the grid shifting system such that the DC powered lighting devices may derive power from the electrical circuit that is connected to the grid shifting controller which would manage power to the lighting devices. In embodiments, the DC powered lighting devices may be bulbs, fixtures or the like. In embodiments, the light source of the lighting devices may be LED, fluorescent, incandescent or the like. In embodiments, the DC powered lighting devices may have a battery and be rechargeable from the grid shifting controller via an external power source.

In embodiments of emergency lighting devices and grid shifting lighting devices with LED light sources, an electrical circuit may be used to turn off, turn on or pulse width modulate the output of an LED driver circuit such that the path may be opened or closed to turn off or turn on power delivered to the LED light source such that the amount of power delivered to the LED light source may be reduced by an amount consistent with the pulse width modulation (e.g., dimming, reducing the light intensity or reducing the amount of power delivered by the LED driver circuit to the light sources). The electrical circuit may include two FETs such that the control may be implemented by a voltage level typical of logic circuits such that a significantly higher voltage that may be typical out of an LED driver circuit may be controlled using a much lower voltage. In some embodiments, the output of the LED driver circuit may drive a series chain of LEDs and as such the voltage drop across the series chain of LED may be significantly higher than what would be typical of a voltage of a logic circuit. By way of an example, a series chain of 15 LEDs may be powered by an LED driver circuit. At a constant current of 200 mA, the 15 LEDs would typically see a voltage drop of approximately 50 volts. Passing this through a FET to allow a control facility to turn on, turn off or pulse width modulate this path, the FET would have to be capable of withstanding more than 50 volts and the controlling logic may have to be able to control the FET with voltages as high as or close to 50 volts. To control the LED driver FET that may control the path to the LEDs, a second FET may be used to control the LED driver FET such that when the second FET is turned on, the LED driver FET is controlled to turn off and when the second FET is turned off the LED driver FET would be wired to be normally closed and thus pass power to the series chain of LEDs. The second FET may be controlled by a low voltage typical of the output of logic, a microcontroller, a microprocessor, a low voltage electrical circuit or the like. If the FETs are selected to allow a fast switching speed, a pulse width modulation may be employed to turn the path on and off quickly effectively allowing the control facility implemented with the logic, microcontroller, microprocessor, low voltage electrical circuit or the like to control the amount of power delivered to the light source from the LED driver circuit. It is to be appreciated that N channel FETs, P channel FETs etc may be used in conjunction with the claimed invention and may be wired in any manner to allow logic level control of a high voltage path to a light source. In embodiments of wireless lighting devices that contain an integrated power source, this circuit may allow a control facility to disconnect power to the light sources on the drive side of the LED driver circuit thus allowing the return of the LED driver circuit from an external power source and the return of the step up battery LED driver circuit to be tied together. In embodiments, the light source may be any light source mentioned herein and the two FET control circuit may be used to allow a low voltage device to turn on, turn off or pulse width modulate power delivered to the light source. In embodiments a grid shifting lighting or electrical device may be used in demand response applications, where demand response parameters may be considered to determine when and how to charge the battery. By way of an example, an instruction may be issued by a demand response control system to grid shifting lighting or electrical devices to begin charging the integrated battery source or to schedule the charging of the integrated battery source. In demand response applications, actions taken as a result of dynamic changes in energy prices, demand or peaks in energy usage may necessitate that a demand response control entity control charge cycles of integrated battery sources that may be used to supply some or all of the power for a grid shifting lighting or electrical device.

In embodiments where a grid shifting lighting or electrical device may be used in demand response applications, a demand response control entity may monitor power on one or more lighting or electrical circuits to make a decision based on power consumption whether or not to initiate an action to use an alternate power source. In the embodiments, a demand response control entity may not move power over to an integrated power source unless the entity detects that power consumption crosses some threshold amount of power consumed. By way of an example, if only half of the lights on a lighting circuit are turned on or some of the lights have already been dimmed, then the demand response entity may not need to take an action because power is not being used on that circuit to a level where demand response is necessary. In some embodiments, the demand response control entity may program or configure the grid shifting lighting or electrical devices with the thresholds by which their operation may require a response to a demand response action.

In embodiments, a grid shifting lighting system may contain an external grid shifting controller, where the external grid shifting controller may have a connection to a network, may communicate wirelessly or may communicate over the power lines such that the external grid shifting controller may receive control, configuration and programming or transmit status or responses to an external controlling entity that may control one or more grid shifting lighting systems, and the like. As such, the external controlling entity may control the operation of a large number of grid shifting lighting devices through communication with an external grid shifting lighting controller. The external controlling entity would not have to communicate with every end device nor would it be required to implement a wired or wireless interface and communication protocol into the end devices because the external grid shifting lighting controller may receive higher level commands from the external controlling entity and implement the required lower level commands to control the end devices to operate as required. By way of an example, a grid shifting lighting system may receive configuration information (e.g., a signal, such as a load indication signal, which may include a command such as a command indicating how much power to consume from a particular power source or energy storage device, when to consume power from a particular power source or energy storage device, how long to consume power from a particular power source or energy storage device, what the light intensity is as a result of a power command, program, protocol, RF signal, RF transmission, datagram, packet, frame, or any other suitable type of communicated information) and control from a demand response server or similar hardware such that the demand response may control grid shifting lighting systems that are controlled by an external grid shifting controller. In another example, a smart grid controller or meter may be capable of communicating with an external grid shifting controller to controller one or more grid shifting lighting systems to make use of grid shifting for the purposes of energy efficiency, demand response applications, peak shedding, load control, load leveling, backup power, local power generation and storage or any other use of a hybrid power system mentioned herein.

In embodiments of emergency lighting devices and grid shifting lighting devices, an architecture to provide battery backup as an AC input to AC output in-line battery backup module may be used such that the AC input is converted to DC, then the converted DC input is or'ed (as used herein “OR'ed” and “or'ed” will be used interchangeably with “subjected to the logic function ‘OR’”) with the output of battery that is fed into a conversion where the output is converted through an inverter to create an AC output to the end device. The DC paths, either from the AC input or from the battery integrated into the in-line battery backup module, may be controlled with a switching circuit and to turn on, turn off or pulse width modulate to control whether power is delivered and/or the amount of power delivered to one or more devices powered by the AC output. In some embodiments, an amount of power delivered to the AC output may be monitored such that a control facility of the in-line battery backup module may be able to manage the amount of power delivered from any input source to provide a desired amount of power at the AC output and to draw the desired amount of power from the input sources.

In embodiments, a power outage may be detected in a wall switch or similar controlling device and with no power on the line still control lighting devices or electrical devices using communication over the power lines between the wall switch or similar controlling device and the lighting or electrical devices that are being controlled. It is to be appreciated that power in the wall switch or similar controlling device, lighting device or electrical device may be provided by the power source integrated into those devices to facilitate power outage functionality. In embodiments, the wall switch or similar controlling device may control the lighting or electrical devices as they may with power applied from the line. In embodiments, the wall switch or similar controlling devices may provide means of control during a power outage such as automated control of the lighting or electrical devices in a pre-configured method. By way of example, upon detecting a power outage, the wall switch or similar controlling device may instruct the control facility in a lighting device or electrical device to remain on for some period of time at which point the wall switch or similar controlling device may instruct the lighting device or electrical device to turn off, change light intensity or change mode or method of operation. In embodiments of grid shifting lighting devices or grid shifting electrical devices, input power may be shut off from grid shifting lighting devices or grid shifting electrical devices but power line communication may still allow a grid shifting controller device to continue to configure and control the grid shifting operation in the absence of power.

In embodiments, the battery powered wireless lighting modules may be controlled such that they are turned on when a disruption may be detected where wired lighting devices are controlled. In embodiments, one or more battery powered wireless lighting modules may receive a signal transmitted from a point on the wired power distribution such that the detected state of power turns on, turns off or changes the operation of battery powered wireless lighting modules. In some embodiments, the battery powered wireless lighting modules may contain transceivers allowing battery powered wireless lighting modules to form a network to transmit, receive and forward commands, control and status. In some embodiments, a wall switch controlling wired lighting may contain a wireless transmitter and an integrated power source such as a coin cell battery, rechargeable battery or the like and may operate to control the one or more battery powered wireless lighting modules if a disruption is detected in wired power. In an embodiment where wall switch controls wired lighting, the switches may still control the battery powered wireless lighting modules. By way of an example, a power outage may be detected by the intelligent wall switch. The intelligent wall switch may transmit a control message to one or more battery powered wireless lighting modules to turn on during the outage. When the intelligent wall switch detects that power has returned, it may send a message including a command to turn off one or more battery powered wireless lighting modules. In addition, the intelligent wall switch may control the battery powered wireless lighting modules through the outage such that if a user turns the switch to the on position, an on command is transmitted and the modules turn on. When the user turns the switch to the off position, an off command is transmitter and the modules turns off. In embodiments, the intelligent wall switch may have additional controls on it to control the battery powered wireless lighting modules independent of control of the wired lighting. By way of an example, a separate on/off switch may be on the intelligent wall switch to control the modules. In another example, an intelligent wall switch may have a USB connector that a user may plug a laptop into to control, configure or gather status of the battery powered wireless lighting modules. By way of an example, the user may control and/or run a test of the battery powered wireless lighting modules via a software application on a laptop or similar computer device that may be connected to an intelligent wall switch to illuminate the lights, gather battery capacity status, configure auto-shutoff times or brightness levels etc.

In embodiments, a control facility may monitor the amount of power used over time to determine when to stop or reduce the use of battery power (versus monitoring battery capacity). Knowing the capacity of the battery when it was installed and knowing the history of use of the battery may allow for a battery capacity estimation. An estimate of capacity loss over time using number of charge cycles at given charge rates, temperature, the characteristics of the power consumption of lighting devices powered by the battery may allow an emergency lighting device or grid shifting lighting device to indicate when the battery capacity may be below a threshold such that the device may not meet specification. In some embodiments, a control facility in the emergency lighting device or grid shifting lighting device may use the information to change the mode of operation (brightness level at start, brightness profile over time, amount of use of battery, charge rates, etc.) to extend the usable battery life.

In embodiments, an LED light fixture with an LED light source and an intelligent driver module that contains an integrated rechargeable battery and the ability to drive the LED light source from the battery as well as the ability to drive the LED light source from a connection to grid power. Intelligence in the form of a microcontroller, microprocessor, programmable logic or the like may control the amount of power consumed in each path (e.g., the path from the battery and the path from the grid). The intelligence may implement control of the amount of power consumed in each path through pulse width modulation control of two switching circuits to allow the two paths to be combined and the amount of power supplied from each path to be controlled via the pulse width modulation. This may allow for control of the amount of power consumed from each path therefore any amount of the power supplied to the light source may be shared between the two sources of power. Multiple methods of control implemented by the integrated intelligence may be provided to make a decision on when to perform grid shifting and how much power to shift. One method may be time of day and and/or calendar based. The intelligence may maintain an accurate time of day clock and be capable of maintaining a schedule of when to activate or deactivate grid shifting and by what amount. At each entry in the schedule, the intelligence may change the control of the two paths. In addition, the integrated intelligence may be capable of scheduling charge cycles for the rechargeable battery such that the energy storage device may be charged at the optimal time depending on the application. Time scheduling may be used as a trigger to power the light fixture during a power outage. By way of an example, if full light intensity is required from the fixture during work hours, the light fixture can be programmed to automatically power the light source from the battery during work hours when it detects that the grid connection is no longer providing power. Another method may be the reception of a load control signal from an external controller. This method correlates to an interrupt from an external control source to reduce demand on the grid or return to normal operation. In the context of a grid shifting light fixture, the load control command may contain the amount of power consumption to be shifted and for how long. Time based and load control based methods of triggering grid shifting may have practical application in peak shedding, demand response and other load control mechanisms that may be desirable to a power provider. The grid shifting lighting device may contain a communication interface. A software application may run on a separate device such as a laptop, computer, handheld device, server or the like that allows a user to enter the parameters for grid shifting such that those parameters may then get communicated to the grid shifting lighting device. A user interface may create and format for the commands that get transferred from the user interface through the communication interface to the intelligence on the lighting device. In some embodiments, the grid shifting lighting device may have a transceiver such that one or more grid shifting lighting devices may form a network to receive and/or forward commands or data throughout a network of grid shifting lighting devices. The communication interface may be any type of wired or wireless interface described herein.

Referring to FIG. 12, the present invention may provide for power outage management through a lighting facility 1202A-H and a power outage detection device 1214 connected to power distribution 1218, where the lighting facility 1202A-H may include an LED lighting source 1204, a control facility 1208, an internal power source 1210, a power outage input device, and the like. In embodiments, the power outage detection device 1214 may detect a power outage in the power distribution 1217, and as a result, transmit a power outage signal to the power outage input device 1212 of the lighting facility 1202A-H. The control facility 1202 may then manipulate the LED lighting source 1204, such as turning on, turning on in a dimmed state, flashing, flashing momentarily, changing the spectral output, and the like. In addition, in the case when the lighting facility 1202A-H also has a connection to AC power, such as through the power distribution 1218, the control facility 1208 may switch power to the internal power source 1210. In embodiments, each of the lighting facilities 1202A-H may be set to respond differently, or in groups. For instance, a group of lighting facilities 1202B-D may be located in a hallway or stairway, and they may respond together in a way that provides pathway lighting in those areas; a pair of ceiling lights 1202F-G may respond together, or separately per their different positions in the room; an individual room light 1202E may be controlled separately; a portable emergency light 1202H may be set to glow when responding to help an individual find it during the power outage; and the like.

In embodiments, the present invention may provide for a power outage lighting management within an environment, comprising a power outage detection device adapted to detect a power outage condition and to wirelessly transmit power outage indication data to a plurality of lighting systems within the environment, where at least one of the plurality of lighting systems include an LED light source that is powered by an internal power source. In embodiments, at least one of the plurality of lighting systems may include a light source that is powered by either the internal power source or an external power source. In response to receiving the power outage power indication data, the lighting system including the LED light source that is powered by the internal power source may regulate a light intensity of the LED light source in accordance with the power outage indication data, such as the light intensity as a dimmed light condition, the light intensity as a full brightness light condition, and the like.

In embodiments, the present invention may provide for a power outage management for a plurality of lighting sources, comprising at least one of a plurality of lighting facilities containing an LED lighting source, a power outage input device, an internal power source, a control facility for manipulating the light output of the LED lighting source, and the like, wherein the lighting facility may provide light in response to a power outage signal received by the power outage input device indicating a power outage condition; and a power outage detection device that monitors power at some point in power distribution to detect the power outage condition, where the power outage detection device may wirelessly transmit the power outage signal to the power outage input device of the at least one of the plurality of lighting facilities when the power outage condition is detected. In embodiments, the outage input device may contain a wireless receiver to receive the power outage signal. The response may be provided with an environmental input from a sensor input device in the lighting facility in addition to the signal received by the power outage input device. The lighting facility may take the form of at least one of a light bulb that mounts into a lighting fixture, a lighting fixture, a retrofit lighting fixture, a lighting adapter, a battery powered lighting fixture, and the like. The centralized controller may be running a software control program. The signal may be received from a web-based source. The web-based source may be on a local network, on the Internet, and the like. The internal power source may be a rechargeable energy storage device integrated with the lighting facility that is capable of supplying power to the lighting facility independent of the power distribution, and where the recharging may be provided internal to the lighting facility at a time when the power distribution is available. The rechargeable energy storage device internal to the lighting facility may be a battery, fuel cell, super capacitor, and the like. The lighting facility may be disconnected and used as a portable lighting device. The sensor may sense infrared, temperature, light, motion, acoustic, smoke, electromagnetic, vibration, and the like. The manipulating may be switching on the light output, changing the illumination level of the light output, flashing the light output, changing the color content of the light output, and the like. The power outage module may contain an integral power source. The power outage module may contain a light source, where the power outage module may be disconnected from a power source and used as a portable lighting device. The response may be provided with an environmental input from a sensor input device in the centralized controller. The centralized controller may contain pushbuttons, switches, dials, and the like to control the lighting facilities remotely. The centralized controller may be a power outage module monitoring an emergency lighting circuit to detect an indication that emergency lighting must be activated. In this way, the power outage device may be connected to an emergency lighting circuit (e.g., not part of power distribution) but it would allow a wireless extension of the emergency lighting circuit. In embodiments, the present invention may provide a detached lighting system that could be supplemental to an installed emergency lighting system by propagating the control through a connected power outage device to the lights.

In embodiments of the Wireless Emergency Lighting System the power failure detection device may be hard wired or permanently connected to a junction box, wall outlet, wall switch etc. In such an embodiment the power failure detection device may contain all of the circuitry described when plugged into a wall outlet however it may be hard wired to a device with connectivity to detect a disruption of power of a power source that may transmit to one or more battery powered wireless lighting fixtures to turn on, turn off or change state based on a change of state of the monitored power source. By way of an example, a power outage failure detection device may be integrated into a wall switch. The power outage failure detection device may detect a state of the power source. The power outage failure detection device may include a power monitoring circuit, a wireless transmitter, an integrated power source such as a rechargeable battery and a processor to monitor the state of the power source, process the state and transmit a change of state to the one or more battery powered wireless lighting device. In this example, the power outage failure detection device may also detect the position of the wall switch and transmit information about the intent of the user with respect to the position of the wall switch. If the user intended to turn the lights off, the power outage failure detection device may not transmit control to turn on the battery powered wireless lighting devices or alternatively even if the user intended to turn the lights off, the power outage failure detection device may transmit control to change the state of the battery powered wireless lighting devices. In another embodiment, the power failure detection devices may be designed into a wall outlet. In an embodiment, the power failure detection device may be designed as a module that connects to a junction box such that it may have an electrical connection to the power source passing through the junction box and may detect a disruption in the power source and transmit control to battery powered wireless lighting devices. In some embodiments, the power failure detection device may have a wired or wireless interface to allow it to receive commands such that a user or installer may program the operation of the device. In embodiments, the device may receive a transmission from another power failure detection device or some alternate controller such that a network of power failure detection devices may be instantiated. The power failure detection network may allow an extension of the network beyond the range of the transmitter in a power failure detection device. In embodiments the battery powered wireless lighting devices may contain a wireless transmitter and receiver allowing the power failure detection network to be extended through a network of battery powered wireless lighting devices that may propagate control information through the network to detection devices and wireless lights beyond the range of the original control sources.

In embodiments, an emergency lighting function may be integrated into an LED light bulb or compact fluorescent light bulb by integrating an LED light source and a power source such as a battery into the bulb where the LED light source and integrated power source operate on a detected power outage, bulb failure or any detected condition that may require the backup light source to be illuminated. In these embodiments, a processor or electrical circuit may be present to detect the outage and control the illumination of the backup light source in the bulb. The integrated power source may be rechargeable such as a super capacitor or rechargeable battery that would allow the storage of energy to be used during a power outage, bulb failure or any detected condition that may require the backup light source to be illuminated. The LED light bulb or compact fluorescent light bulb may operate independent of the backup light source integrated into the bulb. In embodiments of compact fluorescent light bulbs, the backup light source, power source and circuitry may be designed into the section of the housing containing the electronic ballast such that when the outage or failure is detected, the light source within the electronic ballast housing is illuminated. In some embodiments, a switch sense function may be integrated into the LED light bulb or compact fluorescent light bulb to add the ability of the emergency lighting function to be able to detect the state of controlling devices to allow the processor or electrical circuit to use the state of the controlling devices to decide on whether to illuminate the backup light source with the integrated power source. In embodiments that detect a bulb failure, there may be additional electrical circuitry which may monitor the primary light source to determine if there has been a failure of the primary light source. By way of an example, a current sensing may be implemented to determine if current is flowing through the primary light source. In a case where the primary light source has power applied but no current is flowing through the primary light source, the processor or electrical circuit may detect that as a failure of the primary light source. In an embodiment, a light sensor may be used to detect a failure of the primary light source (e.g., it may detect a light source outage).

In embodiments, a light fixture may contain two sockets. In one socket a regular light bulb may be installed and in the other socket a UPS or battery backed light bulb may be installed that only operates when a disruption in power is detected. The size and type of socket for primary and backup lighting may be any size or type to support any bulb mentioned herein as required by the application. The UPS light bulb may contain any functionality mentioned herein. By way of an example, the light source may illuminate during rolling or scheduled blackouts (e.g., regular power outages schedule by the power utility). In an embodiment, the trim of a fixture may contain a light source and a battery backup or similar local power source such that the light fixture trim may be illuminated powered by the battery backup when a disruption of power is detected. In an embodiment, the one of the two sockets of the fixture may be driven by an external battery backed inverter that may be capable of detecting a power outage and supply power from a backup power source. In embodiments, the device with two sockets may be designed in any size or shape lighting fixture housing.

In embodiments, a power outage light bulb may be designed in which the light source may solely be driven by an integrated power source such as a battery. In such an embodiment, the external power source may have an electrical connection to the bulb however the external power source may be used for other reasons such as to detect a disruption of power, to recharge an integrated battery, to allow a switch sense circuit to detect the state of the switch, for external communication over the wired connection and the like. By way of an example, a power outage light bulb may have a connection to AC power through an Edison base. The power outage light bulb may contain a recharge component powered from the AC power input and an LED light source. The power outage light bulb may detect whether AC power is present or not and may contain a processor or electrical circuitry to connect battery power to drive the LED light source based on the detection of the presence of AC power. By way of an example, a power failure light bulb may be designed that illuminates the light source using the integrated power source when AC power is absent at its wired input. In an embodiment, the power outage light bulb may contain switch sense circuitry such that it detect whether a controlling device such as a wall switch may be in an on or off position. In embodiments, the power outage light bulb may be integrated into an emergency lighting device or fixture to meet electrical code for emergency lighting where the power outage light bulb converts a normal fixture in to an emergency lighting device or fixture that meets code. In some embodiments, a method of wireless control may be integrated into the power outage light bulb to provide additional methods of control. In one embodiment, a power outage light bulb may include a wireless receiver or transceiver such that it may be controlled independent of its wired interface. In another embodiment, a power outage light bulb may include a motion sensor. In such an embodiment, the power outage light bulb may be capable of operating during a power outage but may also provide general illumination as controlled by the motion sensor and powered by the integrated battery. It is to be appreciated that embodiments of the power outage light bulb may contain any form of wireless control mentioned herein.

In embodiments, an emergency lighting device may be designed that is controlled only by a light sensor. If the detected light level drops below a certain threshold, the emergency lighting device may illuminate powered by an integrated battery source. Thus, a switch may apply power to the light source in response to the detected light level (e.g., a light sensitive switch). When power is returned and the light source is illuminated, the control component may reset the light sensitive switch to normal mode. In some embodiments, a light sensitive switch may also be part of a light bulb with a small light source and battery that is only activated when it detects no ambient light. In some embodiments, the light sensitive switch may also have a time of day clock that may be combined with the output of the light sensor to determine when to switchover. By way of an example, the light sensitive switch may only be enabled at certain times of day.

In one embodiment, a power failure detector may control wireless lighting devices that have a connection to external power and additionally contain an integrated power source. By way of an example, a light fixture or luminaire may be designed with a connection to AC power, a light source, an integrated rechargeable battery and a wireless receiver that may receive control from a power failure detector. In normal operation, the light fixture or luminaire may be controlled by a wall switch to turn on or off the light source. In the event that a power failure detector detects a disruption in AC power, it may transmit a control message to the light fixture or luminaire to turn on the light source powered by the integrated battery. In some embodiments, the integrated battery may be large enough to sustain a high light intensity to provide general illumination for an area. In one embodiment, a task lighting fixture used in a manufacturing facility may be attached to a work bench. In some locations, the power utility may schedule power outages for extended periods of time due to capacity limitations. In such a case, a power failure detector or remote control may transmit to the task lighting fixture to switch to battery power. The light intensity may be at or close to full intensity allowing a worker at the bench to continue working through the scheduled outage. A task lighting fixture such as this would allow work to continue through an outage therefore limiting productivity losses that may be experienced due to a loss of usable light. Thus, the task lighting fixture of a Wireless Emergency Lighting System and power outage detector operate as a grid shifting system where the grid shifting function is required as a result of the power outage. It is to be appreciated that any lighting device with a connection to external power, an integrated power source, a light source and a wireless receiver may receive control from a power outage detector, remote control or other transmitting device to control to provide illumination during a power outage or to provide a higher light intensity for general illumination to allow for normal activity during the outage. It is to be appreciated that by distributing battery power in the lighting devices, the need for a generator or large energy storage device to support the lighting installation may be reduced or eliminated.

In some emergency or power outage lighting system embodiments, control of emergency or power outage lighting functionality may be distributed over a wide area network such as a 2.5G, 3G, wireless broadband etc network where a wide area network receiver or transceiver in the lighting device may provide the ability for an external control device attached to the wide area network to communicate with and control the end device. In some embodiments, a battery powered wireless lighting module may receive power outage information or control through a wide area network connection and be able use its integrated power source based on the control received over the wide area network. In some embodiments, a battery backed wireless lighting device with a connection to external power may receive power outage information or control through a wide area network connection and be able use its integrated power source based on the control received over the wide area network. By way of an example, an externally powered battery backed wireless lighting device may be designed as a street lamp that is normally powered by an external power source (such as AC power). During a power outage the lighting device may receive a command via a 3G receiver to power the light source using the integrated battery. When the power outage is over, the lighting device may detect the return of power or receive control from the 3G network to return to using the external power source. In embodiments, an external controller that may control one or more emergency or power outage lighting devices may receive control over the wide area network. The external controller may then control the one or more lighting device to operate as required during emergency or power outage situations. By way of an example, a server installed in a commercial building may have a 3G connection and may receive commands to control the lighting installation during an emergency or power outage situation. The server may have a wired or wireless connection to the emergency or power outage lighting devices such that it may command the devices to use the embedded battery power during the emergency or power outage situation. In some embodiments, the control received over the wide area network may be to schedule the use of the embedded power source of a lighting device. In cases where a schedule power outage or rolling blackout may be common, control may be distributed to controllers or lighting devices to schedule the use of the embedded battery power throughout the lighting installation. An advantage of using a wide area network may be that it does not require any additional infrastructure to provide the communication from an external controlling source to the emergency or power outage lighting system. A power utility or other service provider may be able to control end devices during an emergency or power outage without having to alter or add to the infrastructure of an end customer. In embodiments, the power outage indication received via a wide area network may extend to any type of device requiring a power outage indication and may provide a control during a power outage for devices such as a lighting device, lighting adapter, lighting fixture, troffer, lamp or lamp base, ballast, lighting power supplies, lighting control device and the like, television, television peripheral, computer, servers, network equipment, storage devices, appliance, washer, clothes dryer, refrigerator, freezer, electric range, microwave oven, electric water heater, vacuum cleaner, cell phone charger, stereo, air conditioner, HVAC devices, electric or hybrid vehicles, electric motors, portable generators and backup power sources, uninterruptable power supplies (UPS), inverters, industrial and manufacturing machinery etc.

In embodiments, a system may be created including a Power Outage Ceiling/Task Lighting Device with a Wireless Receiver having a connection to external power, an integrated power source and a wireless remote control such that a user may turn on the light source powered by the integrated power source during a power outage via the wireless remote control. In some embodiments, the wireless remote control may be a power outage module that is connected to a power source to monitor whether the power source is available or not and transmit to one or more Power Outage Ceiling/Task Lighting Device with Wireless Receiver to turn the light sources on during a detected outage. In some embodiments, the Lighting Device may contain a real time clock to maintain time of day or a calendar. In some embodiments, the wireless remote control may provide an interface to program the Lighting Device allowing the Lighting Device to be programmed to operate based on time of day. In the case where power outages are scheduled, with knowledge of the schedule a user may program the lighting device to operate automatically to provide a light source through the outage. In normal operation, the Power Outage Ceiling/Task Lighting Device with Wireless Receiver may operate powered from the external power source and may be controlled by a power delivery switch such as a wall switch such that the wall switch may turn the Lighting Device on and off, dim or control in any other manner mentioned herein with a second form of wireless control allowing a user to operate the Lighting Device through the wireless receiver using the wireless remote control independent from or in conjunction with the external power source. In some embodiments, the battery may be recharged if needed while external power is applied and when power goes out a user may turn on the light powered by an integrated power source the wireless remote control. A user may turn on a room full of Power Outage Ceiling/Task Lighting Devices with a single remote control. It is to be appreciated that a wireless remote control may control one or more Lighting Devices on more than one lighting circuits. By way of an example, a commercial office building can indicate which lights throughout the office will use the backup power source but these lights may be controlled by a single emergency remote. In some embodiments, one or more wireless remote controls may be used to control one or more Lighting Devices on one or more lighting circuits. In some embodiments, the wireless remote control allows a user to dim a light or select from multiple lighting levels to conserve battery power and thus extend the amount of time that usable light is available. The claimed subject matter may be designed in any size or shape housing to meet the requirements of any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g. T4, T5, T8, circular etc.) or down light assembly (e.g. recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting), or the like. It is to be appreciated that any combination of wireless control mentioned herein may be used in conjunction with the claimed subject matter.

In embodiments of emergency wireless lighting devices, a system may be created including a Battery Backed LED Driver Module for LED fixtures containing a connection to external power, an integrated power source, a wireless receiver and the capability to drive the LED light source and a power outage module containing a power outage detector to detect a disruption in power and a wireless transmitter such that the power outage module may control the light source powered by the Battery Backed LED Driver Module via the power outage module. In embodiments, a system may be created including a power outage module and a Battery Backed Ballast with a wireless receiver to perform the functions mentioned herein for fluorescent lighting. In embodiments, the power outage module may be connected to a power source to monitor whether the power source is available or not and transmit to one or more Battery Backed LED Driver Module for LED fixtures to control the light source. In the case of a detected power outage, the power outage module may transmit to the Battery Backed LED Driver Module for LED fixtures to turn the light source on powered by integrated battery power. In some embodiments, the Battery Backed LED Driver Module for LED fixtures may contain a real time clock to maintain time of day or a calendar. In some embodiments, a wireless remote control may provide an interface to program and control the Battery Backed LED Driver Module for LED fixtures allowing the Battery Backed LED Driver Module for LED fixtures to be programmed to operate based on time of day. In some embodiments, the Battery Backed LED Driver Module for LED fixtures may be configured to perform grid shifting to transfer some of all of the power consumed to be supplied by the integrated battery. In the case where power outages are scheduled, with knowledge of the schedule a user may program the driver module to operate automatically to provide a light source through the outage. In normal operation, the Battery Backed LED Driver Module for LED fixtures may operate the light source powered from the external power source and may be controlled by a power delivery switch such as a wall switch such that the wall switch may turn the light source on and off, dim or control in any other manner mentioned herein with a second form of wireless control allowing a user to operate the driver module and light source via the wireless receiver using the power outage module or wireless remote control independent from or in conjunction with the external power source. In some embodiments, the battery may be recharged if needed while external power is applied and when power goes out a user may turn on the light powered by an integrated power source the wireless remote control.

In embodiments of lighting installations where DC power is distributed in a building to provide a power source for lighting, LED lighting devices with an integrated rechargeable battery may be deployed to store energy to provide lighting during a power outage or for grid shifting purposes. In some embodiments a Lighting-2-Grid architecture may be implemented where a return path exists such that a power output from each lighting device may return power back to a grid tie inverter that would allow for returning power to the grid. In embodiments, a lighting device may have a diode OR connection to the return path such that all lighting devices may be capable of returning power to the grid via the ORed connection. The output of each lighting device used for the purpose of returning power to the grid may be electrically connected so that the diode ORing of the lighting devices provides an electrical path in one direction to the grid tie inverter that ultimately returns power to the grid. In an embodiment where AC power is distributed in a building to provide a power source for lighting, the output of each lighting device for the purpose of returning power to the grid may be electrically connected through the diode ORing however the connection of the lighting devices may produce a DC offset on the AC power lines that may ultimately be connected through an electrical circuit that can extract the DC power from the AC power lines. The extracted power may then be returned to the grid through a grid tie inverter.

In embodiments including a grid tie inverter to return power to the grid, an intelligent power delivery switch may be designed to allow a user to leave a wall switch closed to allow grid tie inverter to return power to the grid while the light source remains off. In such an embodiment, the intelligent power deliver switch may apply power to the light but provide an indication to the light that it should remain off. In one embodiment, a triac controlled dimming circuit contained in the intelligent power delivery switch may chop the waveform to the light in a way to communicate that the light should be off but that the grid tie inverter may still return power to the grid. By way of an example, if the triac controlled dimming circuit contained in the intelligent power delivery switch may chop the waveform such that between 99.5% and 99.7% of the waveform may be chopped. When a circuit in the lighting device detects the waveform with those characteristics, it may disconnect power from the light source via a relay or other switching device controlled by the circuitry in the lighting device. The circuitry inside the lighting device may then activate the grid tie inverter circuit to return power to the grid.

In some embodiments, a lighting driver module or lighting device may include electrical terminals (e.g. wires, screws, terminal blocks, connectors etc.) allowing the lighting device to have an electrical connection to an external battery, power supply or power source. By way of an example, a lighting driver module or lighting device may not have an internal power source but may instead have an external battery, power supply or power source that may be wired to through the electrical terminals on the lighting driver module or lighting device. In some embodiments, there may be protection circuitry on the input power from the external power source. In some embodiments, one or more lighting driver modules or lighting devices may be connected to an external battery, power supply or power source. The lighting driver module may be an LED driver module, LED power supply, fluorescent ballast and the like. The lighting device may be any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g. T4, T5, T8, circular etc.) or down light assembly (e.g. recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting), or the like.

In embodiments of power outage devices or grid shifting devices, a battery embedded outlet adapter including an integrated battery, a connection to plug into an electrical outlet, a connector to allow an electrical plug to connect to it and a wired or wireless communication method such that a smart meter or smart grid controller device may communicate with the adapter to switch over to the battery during a power outage or for grid shifting purposes. In embodiments, the battery backed outlet adapter may contain electrical circuitry allowing external power and battery power to be controlled such that some or all power required by one or more connected devices may be supplied by either power source. By way of an example, a battery embedded outlet adapter may plug into a wall outlet such that AC power may come into the adapter. The battery embedded outlet adapter may contain an inverter to convert DC from the embedded battery to AC to power connected devices. An electrical circuit and processor to control the amount of power from input AC power and from embedded battery power may be included in the battery embedded outlet adapter. The smart meter may also have a battery in it to allow it to operate during an outage.

In embodiments of grid shifting lighting devices, a system may be created including a Grid Shifting Ceiling/Task Lighting Device with a Wireless Receiver containing a connection to external power and an integrated power source and a wireless remote control such that a user may turn on the light source powered by the integrated power source during a power outage (such as a scheduled power outage or rolling blackout) or when there is a need to reduce power consumption on the via the wireless remote control. In some embodiments, the wireless remote control may be a power outage module that is connected to a power source to monitor whether the power source is available or not and transmit to one or more Grid Shifting Ceiling/Task Lighting Device with Wireless Receiver to turn the light sources on during a detected outage. In embodiments, the lighting device may be programmable, may have a real time clock, may be AC or externally powered and controlled by a wall switch allowing normal light operation, may allow the battery to be recharged while AC power or external power is applied or when power goes out may allow a user control the light source from the RF remote/controller while powered by the battery power source. In embodiments, a grid shifting module installed on an electrical circuit to determine how much power is being consumed by the circuit may detect the amount of power consumed on a circuit and transmit to a Grid Shifting Ceiling/Task Lighting Device with Wireless Receiver to transfer some of the power consumed to the integrated power source. The grid shifting module may be installed at a wall switch, circuit breaker or any other location in the power distribution to monitor how much power is passing through a point in an electrical circuit. In some embodiments, the Lighting Device may contain a real time clock to maintain time of day or a calendar. In some embodiments, the wireless remote control may provide an interface to program the Lighting Device allowing the Lighting Device to be programmed to operate based on time of day. In the case where power outages are scheduled, with knowledge of the schedule a user may program the lighting device to operate automatically to provide a light source through the outage. In normal operation, the Grid Shifting Ceiling/Task Lighting Device with Wireless Receiver may operate powered from the external power source and may be controlled by a power delivery switch such as a wall switch such that the wall switch may turn the Lighting Device on and off, dim or control in any other manner mentioned herein with a second form of wireless control allowing a user to operate the Lighting Device through the wireless receiver using the wireless remote control independent from or in conjunction with the external power source. In some embodiments, the battery may be recharged if needed while external power is applied and when power goes out a user may turn on the light powered by an integrated power source the wireless remote control. A user may control a room full of Grid Shifting Ceiling/Task Lighting Devices with a single remote control. It is to be appreciated that a wireless remote control may control one or more Lighting Devices on more than one lighting circuits.

By way of an example, a commercial office building can indicate which lights throughout the office will have some or all of their power supplied by internal power. These lights may be controlled by a single wireless remote. In some embodiments, one or more wireless remote controls may be used to control one or more Lighting Devices on one or more lighting circuits. In some embodiments, the wireless remote control allows a user to dim a light or select from multiple lighting levels to conserve battery power and thus extend the amount of time that usable light is available. The claimed subject matter may be designed in any size or shape housing to meet the requirements of any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g. T4, T5, T8, circular etc.) or down light assembly (e.g. recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting), or the like. It is to be appreciated that any combination of wireless control mentioned herein may be used in conjunction with the claimed subject matter.

Control of grid shifting functionality may be distributed over a wide area network such as a 2.5G, 3G, wireless broadband etc network where a wide area network receiver or transceiver in the grid shifting device may provide the ability for an external control device attached to the wide area network to communicate with the grid shifting end device. In some embodiments, a wireless lighting device with a connection to external power and an integrated power source may receive grid shifting information or control through a wide area network connection and be able to transition some or all of the power sourced to an integrated power source based on the control received over the wide area network. By way of an example, an externally powered battery backed wireless lighting device may be designed as a down light in a commercial office building that is normally powered by an external power source (such as AC power). When there is a need to shift power to the integrated power source, the lighting device may receive a command via a 3G receiver to power the light source using the integrated battery. In embodiments, an external controller that may control one or more grid shifting lighting devices may receive control over the wide area network. The external controller may then control the one or more lighting device to perform grid shifting functions. By way of an example, a grid shifting controller may be installed in a commercial building to control one or more lighting circuits. The grid shifting controller may have a 3G connection and may receive commands to control the lighting installation to perform grid shifting functions. The grid shifting controller may have a wired or wireless connection to the grid shifting lighting devices such that it may command the devices to use the embedded battery power in conjunction with or in lieu of the external power source. In some embodiments, the control received over the wide area network may be to schedule the use of the embedded power source of a lighting device. In cases where a schedule power outage or rolling blackout may be common, control may be distributed to controllers or lighting devices to schedule the use of the embedded battery power throughout the lighting installation. An advantage of using a wide area network may be that it does not require any additional infrastructure to provide the communication from an external controlling source. A power utility or other service provider may be able to control end devices for grid shifting purposes without having to alter or add to the infrastructure of an end customer.

With reference to FIG. 13, illustrated is a block diagram of a system 1300 that provides illumination with a wireless light which may be used in embodiments described herein. System 1300 includes a wireless lighting module 1302 that can further comprise an interface component 1304, a battery 1306, an LED controller 1308, LEDs 1310, and/or logic 1312. The wireless lighting module 1302 can be incorporated into a housing (not shown). Any size and/or shape housing can be employed with the wireless lighting module 1302. According to another illustration, the housing can include at least a portion that is moveable (e.g., manually by a user, automatically with a motor or the like) to allow for directing emitted light. For example, a remote control can provide a signal to manipulate a moveable portion of the housing. Moreover, the housing can orient the LEDs 1310 in substantially any manner to provide general lighting (e.g., illuminating an indoor or outdoor area), task lighting (e.g., reading), accent lighting, and so forth. The remote control may also adjust settings associated with reducing power consumption from the battery, grid shifting, peak shedding, load leveling or any other functionality discussed herein. In embodiments, there may be a connection to an external power source such as an AC power source or the like.

The interface component 1304 can receive an input from a disparate device such as a remote control, sensor, another light and the like to, for example, adjust settings associated with grid shifting, peak shedding, load leveling or any other functionality discussed herein. The interface component 1304 can provide various adaptors, connectors, channels, communication paths, etc. to enable interaction with the disparate device. Pursuant to an illustration, the input can be wirelessly transmitted (e.g., via an RF signal, an IR signal) from the disparate device to the interface component 1304; thus, the interface component 1304 can be a receiver and/or a transceiver that obtains the wirelessly transferred signal. By way of example, an infrared sensor or motion sensor can monitor occupancy in an environment and, upon detecting presence within the monitored environment, the sensor can transmit a wireless input to the interface component 1304. It is to be appreciated that any type of sensors can be utilized in connection with the claimed subject matter such as, but not limited to, infrared sensors, light sensors, proximity sensors, acoustic sensors, motion sensors, carbon monoxide and/or smoke detectors, thermal sensors, electromagnetic sensors, mechanical sensors, pressure sensors, chemical sensors, and the like. According to another example, any type of remote control can wirelessly communicate with the interface component 1304. For instance, the remote control can be a stand-alone remote control (e.g., the remote control 300 of FIG. 3) and/or incorporated into a disparate device (e.g., incorporated into a key fob, a programmable wireless transceiver integrated in an automobile.). Moreover, the remote control can be a personal computer, a cellular phone, a smart phone, a laptop, a handheld communication device, a handheld computing device, a global positioning system, a personal digital assistant (PDA), and/or any other suitable device; such devices can communicate directly with the interface component 1304 and/or via a network (e.g., local area network (LAN), wide area network (WAN), cellular network). In accord with another example, radio frequency identification (RFID) can be utilized to provide the input to the interface component 1304. As such, an RFID tag associated with a user can be detected when in range of the interface component 1304, and lighting preferences of the particular user (e.g., retained in memory) can be effectuated in response to the detection of the user.

Additionally or alternatively, the interface component 1304 can be a sensor that can monitor a condition associated with the wireless lighting module 1302 to generate the input. According to another example, the interface component 1304 can be a connector, port, etc. that couples to such sensor.

Further, the interface component 1304 can wirelessly transmit data (e.g., feedback, related to a current and/or anticipated future state) to a remote device and/or sensor. By way of another example, the interface component 1304 can wirelessly communicate with an interface component of a disparate wireless lighting module to enable coordinated operation between more than one wireless lighting module. Following this example, an input can be retransmitted within a network of wireless lighting modules, where the network of lighting modules can be dispersed within a geographic area.

An interface component 1304 integrated into the wireless lighting module 1302 that allows it to be used stand alone, a sensor on the wireless lighting module 1302 used for input or by a remote control that provides input wirelessly to the wireless lighting module 1302, as described herein (e.g., not connected by wire to the wireless lighting module 1302) may be defined as wireless control. Wireless control allows the installation of the wireless lighting module 1302 in any indoor or outdoor location where light may be desired without the need for a wired connection to control it.

The battery 1306 can be any number and/or type of battery. For instance, the battery 1306 can be a rechargeable battery. According to another example, the battery 1306 can be a non-rechargeable battery. The battery 1306 supplies power to the wireless lighting module 1302 to enable installing, moving, replacing, etc. the wireless lighting module 1302 at substantially any indoor or outdoor location while mitigating the need for expensive and time consuming wiring and/or utilization of aesthetically unpleasing and potentially inconvenient cords commonly associated with conventional lighting.

The LED controller 1308 can obtain instructions from the logic 1312 to control operation of the LEDs 1310 as well as power management. For example, the LED controller 1308 may adjust settings associated with reducing power consumption from the battery, grid shifting, peak shedding, load leveling or any other functionality discussed herein. The LED controller 1308, for example, can receive and effectuate instructions to switch one or more LEDs 1310 on and/or off, change an intensity of illumination (e.g., brightness), switch a wavelength of light emitted from the LEDs 1310 (e.g., to change light color), manipulate direction of illumination (e.g., by moving, rotating, etc. one or more of the LEDs 1310). It is contemplated that any number, type, color, arrangement, etc. of LEDs 1310 can be utilized with the wireless lighting module 1302.

The logic 1312 employs the input obtained by the interface component 1304. The logic 1312 can further include a state modification component 1314, a timer component 1316, an intensity regulation component 1318, and/or a wavelength control component 1320; however, the logic 1312 can include a subset of these components 1314-1320. The state modification component 1314 may utilize input obtained via the interface component 1304 to generate an instruction to change a state of one of more of the LEDs 1310. The state modification component 1314 effectuates transitioning one or more LEDs 1310 to an on state, an off state, etc. Further, the state modification component 1314 can yield commands to strobe one or more LEDs 1310 (e.g., periodically turning LED(s) 1310 on and off with substantially any periodicity). The state modification component 1314 can decipher that a received input pertains to one or more of the LEDs 1310. Moreover, the state modification component 1314 can analyze the input to determine whether to instruct the LED controller 1308 to change the state (e.g., compare an input from a sensor to a threshold, evaluate whether a condition has been met, based upon retrieved instructions corresponding to the input retained in memory.). The state modification component 1314 can also adjust settings associated with reducing power consumption from the battery, grid shifting, peak shedding, load leveling or any other functionality discussed herein

The timer component 1316 can operate in conjunction with the state modification component 1314. For instance, the timer component 1316 can enable delaying state changes. Thus, turning the LEDs 1310 on or off can be delayed for an amount of time by the timer component 1316. Further, the amount of time for the delay can be predetermined, randomly selected, included with the input obtained by the interface component 1304 (e.g., based on a number of times a button of a remote control is depressed), etc. According to another example, the timer component 1316 can conserve battery life by enabling the state modification component 1314 to switch the LEDs 1310 to an off state at a particular time of day, after an elapsed amount of time subsequent to an input that turned the LEDs 1310 to the on state, and so forth. Pursuant to another illustration, the timer component 1316 can operate in conjunction with the intensity regulation component 1318 and/or the wavelength control component 1320 described below.

The intensity regulation component 1318 can alter the intensity (e.g., brightness) of the LEDs 1310 based upon the received input from the interface component 1304. The intensity can be changed by the intensity regulation component 1318 adjusting a proportion of LEDs 1310 in an on state to LEDs 1310 in an off state. Additionally or alternatively, the intensity regulation component 1318 can control the intensity of light emitted by each of the LEDs 1310. According to an example, the interface component 1304 can obtain RFID related input that identifies the presence of a particular user, and this user can have lighting preferences stored in memory (not shown) associated with the wireless lighting module 1302. Following this example, the particular user's preferences may indicate that she desires the LEDs 1310 to be dimly lit, which can be effectuated by the intensity regulation component 1318. Pursuant to another example, upon a smoke detector or carbon monoxide detector sensing smoke or carbon monoxide, respectively, the intensity regulation component 1318 can increase the brightness of the illumination of the LEDs 1310 to a highest level (e.g., while the state modification component 1314 can strobe the LEDs 1310, the wavelength control component 1320 can change the color). It is to be appreciated, however, that the embodiments are not limited to the aforementioned examples.

The wavelength control component 1320 can change the wavelength (e.g., color) of light generated by the LEDs 1310 as a function of the input obtained by the interface component 1304. For example, the LEDs 1310 can be color changing LEDs, and the wavelength control component 1320 can yield commands to adjust the color based upon the input obtained by the interface component 1304. By way of another example, the LEDs 1310 can include subsets of LEDs that yield differing colors, and the wavelength control component 1320 can select which of the LEDs 1310 to turn to the on state to yield the desired color.

A building wireless lighting kit may be comprised of wireless lighting devices or wireless lighting modules where the wireless lighting devices are installed in an area such as a room, residence, floor of an office building etc where there may not be a need for wall switches, dimmer switches etc. In such a kit, the wireless lighting devices may contain forms of wireless power and wireless control to allow them to be completely disconnected from and act with respect to the grid. In some embodiments, the building wireless lighting kit may contain a connection to the grid to power the wireless lighting devices however the wireless lighting devices may not have wired mechanisms to control them on individual lighting circuits. The lighting devices in the building wireless lighting kit may contain wireless controls and have intelligence built in such that no controlling switch may be necessary. By way of an example, a residence may be built without any wall switches. The wireless lighting devices may contain wireless control mechanisms such as motion sensors, light sensor etc. The wireless lighting devices may contain a processor that may be programmed to manage control of the building wireless lighting kit. The wireless lighting devices may contain a wireless receiver or wireless transceiver allowing the devices to be controlled by a remote transmitter or by a disparate wireless lighting device allowing coordinated operation by a group of wireless lighting devices. In one embodiment, the wireless lighting device may be a ceiling light that contains a motion sensor, light sensor, wireless transceiver, a processor with a real time clock and a connection to external power. Also in this embodiment, the kit may include a software program and a transmitter or transceiver that may be connected to a computer running the software program such that it may program, configure, gather status from etc the ceiling lights in the kit. With no controlling switch on the wired connection to external power, the wireless lighting devices would be controlled on by the wireless control mechanisms available to it. In a building wireless lighting kit, the wireless ceiling lighting devices may be installed throughout a room or floor of a building and be controlled only by wireless control or programmed by the software program, computer and connected transmitter.

In embodiments, a wireless proximity aware remote control device that turns on the lighting devices that are closest in proximity to remote control may be implemented. In such an embodiment, the lighting devices may contain a mechanism to measure the range to the remote control and determine if it is the within range to be controlled by the remote control. The lighting devices may be programmed or configured with a desired range such that when control is received from the remote control, if the light device determines that it is within the pre-programmed range, it will be act on control or commands received by the remote. In some embodiments, the lighting devices are wireless lighting modules. In some embodiments, lighting devices may be grouped together such that they may coordinate operation to function in a coordinated fashion to turn on, off, dim or modulate operation of the light sources as commanded by the remote control. In some embodiments, there may be two way communications between the wireless proximity aware remote control device and the lighting devices. If a group of lights receive control or a command from the wireless proximity aware lighting device, the lighting devices may respond to the command such that the first response received by the wireless proximity aware remote control determines which group of lights is within proximity. Then the wireless proximity aware remote control may send a second command with a group identifier in it such that it only control the lighting devices that had been previously determined to be closest in proximity to the remote control. In some embodiments, the range between the remote control and one or more lighting devices may be determined prior to the control being sent. With a range information table, the wireless proximity aware remote control may be able to send control or commands to the one or more lighting devices within a set range as programmed in the wireless proximity aware remote control. The method to determine proximity or a distance between the remote control and lighting devices may include but is not limited to round trip delay, time of arrival, use of global positioning satellites (GPS), signal strength, localization techniques using wireless networks such as Wifi, Zigbee etc, infrared, sonar, radar and the like. The wireless proximity aware remote control and lighting devices may contain tightly synchronized clocks to determine time of arrival. By way of an example, a user may be in one room in a residence holding a wireless proximity aware remote control and want to control the lighting in only that room. The user may push a button to illuminate the lights on the wireless proximity aware remote control. The wireless proximity aware remote control may transmit a command to all of the lighting devices within range. This command may contain a timestamp at the time of transmission. Upon receiving the transmission, the lighting devices may time stamp the received time and compare it to the transmit time stamp. If the difference in time from the transmit time to the received time is less than some preset threshold then the lighting device may be within range of the remote control such that it should act on the remote control command. If a lighting device is beyond the range as determined by the time of flight calculation, perhaps in a adjacent room, then it should not act on the remote control command. In some embodiments, light devices throughout an area may communicate between themselves independent of the remote control to synchronize clocks, set up groups or operate in a coordinated fashion.

In embodiments, a disparate device such as a remote control, a remote sensor, another light, a power outage module and the like may alter the transmit power out of a transmitter as a means to control lights located at different ranges with respect to the disparate device differently. In some embodiments, the disparate device controls a wireless lighting module or an externally powered battery embedded wireless lighting device wherein the receiver within the module or device may receive the control from the disparate device. By way of an example, there may be four buttons on a remote control that a user may push. Buttons on the remote control may provide on and off control to all of the wireless lighting modules within a one hundred foot range by transmitting a 10 mW power level control signal or message to all modules within that range. Buttons on the remote control may provide on and off to all of the wireless lighting modules within a fifteen foot range by transmitting a 1.5 mW power level control signal or message to all modules within that range. Further, the wireless lighting modules may be installed throughout a home. By using the different buttons, a user may turn the lights on and off only in the room they are in by using the low power transmit buttons and turn on and off the lights throughout the house by using the high power transmit buttons. It is to be appreciated that any command for lighting including on, off, dimming, color, timing, configuration or programming of lights and the like may be used in connection with the claimed subject matter.

In embodiments, a disparate device such as a remote control, a remote sensor, another light, a power outage module and the like may be capable of transmitting on different control channels as a means to control lights differently located within range with respect to the disparate device. In some embodiments, the disparate device controls a wireless lighting module or an externally powered battery embedded wireless lighting device wherein the receiver within the module or device may receive the control from the disparate device with the control channel being part of the control message. By way of an example, there may be four buttons on a remote control that a user may push on a power outage module. One button on the remote control may provide on and off toggle control to all of the wireless lighting modules within range that are configured to be controlled by a first channel wherein the control signal or message contains an indication of the first channel to control all modules within range. A second, third and fourth button on the power outage module may provide on and off toggle control to all of the wireless lighting modules within range that are configured to be controlled by a second, third and fourth channel respectively wherein the control signal or message contains an indication of those channels to control all modules within range. Further, the wireless lighting modules may be installed throughout a home. By using the different buttons, a user may turn the lights on and off only in an area or zone designated by a particular channel setting. In some embodiments, a wireless lighting module or an externally powered battery embedded wireless lighting device may be configured to respond to more than one channel. In embodiments any number of channels or any format by which one or more devices or modules can be addressed in the command to direct a command to those devices or modules may be implemented. It is to be appreciated that any command for lighting including on, off, dimming, color, timing, configuration or programming of lights and the like may be used in connection with the claimed subject matter.

A wireless lighting system may be comprised of battery powered wireless lighting devices or wireless lighting modules that have an input jack to receive external power, a rechargeable battery inside, a recharge component, a light source, one or more sensors and RF control, an energy harvesting mechanism such as solar panels, wind mills etc and power cabling to cable power from the energy harvesting mechanism to the installed battery powered wireless lighting devices. In one embodiment, a residential house contains an installation of recessed LED light fixtures that are battery powered wireless lighting devices that have a rechargeable battery, recharge component, DC input and wireless control. The residential house may contain solar panels on its roof top. A power bus from the solar panels may be wired throughout the house such that a power feed plugs into all of the recessed LED light fixtures throughout the house. The battery powered wireless lighting devices may be controlled by motion sensors, light sensor or wireless receiver such that the lights may be turned on, off, dimmed etc remotely by a user. In this embodiment, the batteries may charge during day and be used at night or in day if needed. One or more windmills are adjacent to the residence and a power bus is cabled from the windmills to the residence. In this case, the batteries may be charged during the day or at night. In an embodiment, a second plug in point may be accessible to allow a generator to be plugged in for use if the battery charge is not kept high enough for the lighting devices to operate properly. Assuming 10 W of power required for each fixture, then if there are 20 fixtures lighting for the entire house requires 200 Whr of power. To providing lighting for 5 hours a day requires approximately 1 KWHr per day. In embodiments, a plug in receptacles for lamps may be developed that may allow similar operation of the lamps designed as battery powered wireless lighting devices.

In embodiments, a processor or electrical circuit may provide a mechanism to reduce current through the LED light source when batteries capacity falls below a threshold to lessen the chance that the motion sensor would false trigger when LED light source is turned off. In cases where a motion sensor may be in the wireless lighting device, when the battery provides power to the LED light source, the battery voltage may drop significantly due to the high power consumption of the LED light source. When the motion sensor does not detect motion for some period of time the light source may turn off and the voltage level may increase significantly and quickly potentially causing the motion sensor to falsely trigger. In such a case, reducing the amount of power required by the LED light source may reduce the size of the voltage swing from light source on to light source off and reduce or eliminate the chance of a false trigger. By way of an example, an LED spotlight with a 2 W LED light source, a motion sensor and 3 D cell batteries may detect motion and turn the light source on. Prior to motion detected when the light source is off, the battery voltage may be measured at 4.0V. After the light source is turned on, the battery voltage may be measured at 3.4V. This is caused by the heavy load on the batteries pulling the battery voltage down to a lower voltage. After motion is not detected for some period of time, the light source is turned off and the battery voltage will return to 4.2V in a very short period of time (perhaps in the millisecond range). If upon detecting that the battery voltage has dipped below 4.1V, the processor that controls the current drawn by the LED light source may reduce the current draw by some amount. By way of an example, if the processor reduces the current draw by 50%, the battery voltage with the light source on may only be 3.7V thus reducing the voltage swing from light source on and light source off thus reducing or eliminating the chance that there will be false triggers from the motion sensor.

In embodiments, power supply device or control device may include circuitry to detect conditions that may allow an intelligent decision on which power source to use. The switch sensing device may detect whether the controlling switch or breaker applying power to a battery backed AC powered light bulb is open or closed, if input AC power is present, if the quality of the input AC power is acceptable, and the like. The switch sensing device may monitor the presence and quality of the input AC power with circuitry to detect the presence of AC power and make a measurement of the characteristics of the AC power. It may also measure the impedance, resistance, and/or capacitance of the AC power input or may measure any other electrical characteristic of the AC power input to determine whether the controlling switch or breaker is open or closed (or if electricity has been turned off at any point up to the AC input of the switch sensing device). The switch or breaker may be any type of switch or breaker used to control an electrical or lighting circuit such as but not limited to toggle switches, dimmer switches, three way or multi-way switches, timer controlled switches, motion sensor switches, push button or touch switches, paddle switches, solid state switches, slide switches, rotary switches, switches with specialized intelligence built in, open fuses in the electrical or lighting circuit, poly fuses or poly switches, low, medium or high voltage circuit breakers, magnetic circuit breakers, thermal magnetic circuit breakers, common trip circuit breakers, residual current circuit breakers, earth leakage circuit breakers and the like. In some embodiments, the switch sensing device may store information such that one or more associated light sources may be able to operate as it was when the outage occurred. For example, the switch sensing device may be controlled by a dimmer switch, the switch sensing device may store the dim level and when there is a power outage, the switch sensing device may switch to PWM dimming that is similar to the light intensity level that had been set by the dimmer switch, and the like. By way of an example, if the controlling switch or breaker is open, there may be a high impedance detected on the input AC power. If the controlling switch or breaker is closed, there may be a measurable impedance, resistance and/or capacitance or electrical characteristic different from when the controlling switch or breaker is open. A threshold may be set in the bulb such that if the measurement is above or below the threshold, the switch or breaker is closed, and if the measurement is on the opposite side of the threshold, the switch or breaker is open. The switch sensing device and associated one or more light sources may be controlled by the state of the controlling switch or breaker (on or off), but may also detect the condition when the controlling switch or breaker is closed but AC input power is not present or is not acceptable and may be able to switch over to the rechargeable or non-rechargeable batteries that are embedded as the power source. Thus, the switch sensing device may be able to switch to embedded battery power without directly knowing whether the switch is open or closed, but rather by measuring the electrical characteristics of the AC input. In some embodiments, the switch sensing device may have circuitry to be able to detect the switch transition from on to off or off to on. By way of an example, in a power outage, the wall switch may still be used to control the switch sensing device and associated one or more light sources that are powered by battery to on or off such that even when AC is not applied, a transition from switch closed to switch open will turn off the switch sensing device that is powered by the embedded power source.

In some embodiments, the switch sensing device may perform an impedance discontinuity check to determine if the controlling switch or breaker is open or closed. In some embodiments, the switch sensing device may generate a signal onto the line and monitor the electrical response of the line to determine if the response indicates an impedance discontinuity typical of an open circuit that may be indicative of a switch or breaker open in the lighting circuit or if the response indicates a closed circuit typical of a switch or breaker closed in the lighting circuit. By way of an example, the switch sensing device may perform a function typical of a time domain reflectometer by generating a short rise time pulse at the connection to input and monitor the input for a reflected signal that would be indicative of an open or closed circuit. If the reflected signal exceeds a set threshold, it may indicate an open circuit. In some embodiments, the switch sensing device may learn where such a threshold should be set. The switch sensing device may be installed in many variations of lighting circuits where the amount, length, gauge or type of wiring to the switch or breaker may vary and where there may be many other sources of loads on the lighting circuit (such as bulbs, fixtures, multiple switches or controls etc.) therefore it may have to adjust its detection circuitry to operate properly. The setting of the threshold may be done automatically by the switch sensing device or manually by a user through any process that may allow the bulb to be set to a threshold where one side of the threshold indicates the switch or breaker is open and the other side of the threshold indicates the switch or breaker is closed. It is to be appreciated that when the switch sense functionality is implemented, the switch or breaker may still be able to turn on and off power to the switch sensing device and associated one or more light sources even when running off of the embedded battery power source because the switch sensing device may be able to determine if the switch is on or off and apply power or not apply power to the one or more associated light sources based on the switch position. The switch sense circuitry may still be powered along with any other necessary circuitry to implement this function even when the light source is not being powered. In some embodiments, a device may be designed that may be electrically and mechanically attached to an existing switch or breaker of any type mentioned herein such that it may have electrical characteristics that may be easily detected by the switch sensing device in an outage. The device, a switch sensing detection module, may be an electrical circuit that may monitor the state of the switch, open or closed, and whether power is present at the input side of the switch. If there is no input power, whether the switch is open or closed, the device may insert a circuit with the electrical characteristics that may be easily detected by the one or more switch sensing devices on the lighting circuit. This allows the switching sensing device to be able to detect an outage even when the controlling switch or switches are open by allowing it to be electrically connected to the input side of the switch. There may be control on the device such that the user may enable the switch sensing device to turn on when the light switch is open and there is no power at the input of the switch. If this function is disabled, the user may control the switch sensing device and associated one or more light sources by the controlling switch, but if the function is enabled, the switch sensing device may be capable of switching to battery power whether the controlling switch is open or closed. The device may not be attached to a switch or breaker, but is the switch or breaker itself thus the function may be installed by replacing an existing switch or breaker. In embodiments, the device may physically and electrically be connected anywhere in a lighting or electrical circuit that it would be desirable to detect a power outage. In some cases, the switch sensing device may not be able to reliably detect the state of the switch in which case the device may be added to make the detection of the switch state reliable.

Referring to FIG. 14, the present invention may provide a switch sensing lighting unit 1400 capable of detecting the state of a controlling device such that the light source can have an emergency backup that can detect when the user intended to apply power to the light source but power is not present. By way of an example, if the controlling device is a standard wall switch, there would be three states including switch open, switch closed with power applied and switch closed without power applied wherein a switch sensing lighting unit can apply power from a local energy storage device in response to switch closed without power applied. The switch sensing lighting unit 1400 may be comprised of a light source 1402, a power input 1404 in electrical association with the light source and a power supply circuit 1406, an energy storage device 1408, a controller 1410 and a sensor 1412. In some embodiments, the light source may be in the same housing as the other components and in some embodiments the light source may be in a separate housing. In embodiments, a power input 1404 may be adapted to receive power via a power supply circuit 1406 wherein the power supply circuit receives a supply of external power through a controlling device and includes an energy storage device. In one embodiment, the power supply circuit 1406 receives a supply of AC power through a switch and includes a rechargeable battery supplying a source of DC power. The light source 1402 may be comprised of at least one of one or more light emitting diodes (LEDs) light sources, an incandescent light source, a fluorescent light source, a halogen light source or the like adapted to receive power via the power input 1404. A sensor 1412 may be configured to generate an output indicative of an impedance, resistance or capacitance associated with the power supply circuit 1406. A controller 1410 may be configured to determine the operational state of the controlling device through one or more measurements of the sensor output and may cause power from the energy storage device 1408 to be supplied when external power is not present on the power input 1404 and the operational state of the controlling device indicates that the controlling device is in the closed or partially closed state (e.g., is configured to apply power to the power supply circuit 1406). In some embodiments, the controller 1410 may make a plurality of measurements to determine the operational state of the controlling device. The controller 1410 may be configured to determine a first impedance, resistance or capacitance value associated with the power supply circuit 1406 corresponding to an open operational state of the controlling device (e.g., is configured not to apply power to the power supply circuit 1406; in one example it is an open switch). The controller 1410 may be configured to determine a second impedance, resistance or capacitance value associated with the power supply circuit 1406 corresponding to a closed operational state of the controlling device (e.g., is configured to apply power to the power supply circuit 1406; in one example it is a closed switch). The controller 1410 may establish a threshold impedance, resistance or capacitance level based on the first and second values. The controller 1410 may determine a third impedance, resistance or capacitance value associated with the power supply circuit 1406 when external power is not present on the power input 1404 and may cause the power from the energy storage device to be supplied to the light source from the energy storage device 1408 when external power is not present on the power input 1404 and a comparison between the third impedance, resistance or capacitance value and the threshold value indicates the controlling device in the closed state. In some embodiments, the controller 1410 may be configured to allow the threshold value to be manually set. In some embodiments, the controller 1410 may be configured to allow the threshold value to be automatically set by one or measurements of the power supply circuit 1406 wherein the threshold value is determined when the controlling device is in a known state, when the controller 1410 may presume what state the controlling device is in or over a period of time where one or more measurements may provide a statistical sampling that may be used to determine the state of the controlling device. In embodiments, the sensor generates an output indicative of an impedance, resistance or capacitance associated with the power supply circuit 1406 as part of a time domain reflectometry process. In such an embodiment, the sensor 1412 may generate one or more pulses of a given time duration, amplitude etc, monitor the reflective signals and provide a signal to the controller determined by a measurement or analysis of the reflections in response to the one or more pulses corresponding to an impedance discontinuity, impedance, resistance or capacitance associated with the power supply circuit 1406.

In some embodiments, the energy storage device 1408 may be comprised of at least one of a rechargeable battery, non-rechargeable battery such as an alkaline battery, fuel cell, super capacitor, photovoltaic cell or the like. The energy storage device 1408 may be integrated in the same housing with the lighting unit or may be separate from the lighting unit with an electrical connection to the housing. The controller 1410 may be configured to control charging of the energy storage device 1408. In some embodiments, one or more photovoltaic cells may be used to recharge the energy storage device 1408. The switch sensing lighting unit 1400 may be configured for mounting to an Edison socket. In some embodiments, the claimed subject matter may be designed in any size or shape housing to meet the requirements of any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g. T4, T5, T8, circular etc.) or down light assembly (e.g. recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting), or the like. The lighting unit may be configured as a retrofit lighting fixture wherein the unit comprises of a housing configured for installation into a preexisting structure. Thus, a user may install or retrofit an emergency light or power failure light that is capable of performing the switch sensing function into an existing location such that there may not be any additional wiring required to add the emergency lighting or power failure lighting function. Typical emergency lighting installations require an unswitched power connection to detect a power outage but a switch sensing lighting unit 1400 may be able to detect the switch position over existing wiring. In other embodiments, the switch sensing lighting unit 1400 may be designed with the switch sensing function contained in a power device such as power supply, ballast, in-line inverter, LED driver or the like with battery backup wherein a connected lighting device such as one or more LED devices, an LED array, an incandescent light bulb, fluorescent tube or the like may accept power from the switch sensing power device wherein the source of power may be from the power supply circuit 1406 or from the energy storage device 1408 converted to a power output as required by the connected lighting device and determined by the sensor 1412 and controller 1410. In some embodiments, the switch sensing lighting unit 1400 may contain a timer to control the supply of power to the light source. In some embodiments, the lighting unit may contain an environmental sensor such as a motion sensor, light sensor or the like. By way of an example, a light sensor may be used by the lighting unit to sense a level of ambient light and control the supply of power to the light source based in part on the output of the light sensor. The controller 1410 may be configured to control the light source to be on or off, the illumination level of the light source or the color of the light source.

In embodiments, an exit sign providing an illuminated sign for normal and emergency situation may be combined with an integrated power source and switch sense functionality such that the exit sign may be installed on a normal power circuit, e.g., not require a separate emergency power circuit, and that the exit sign may distinguish between the power delivery switch open, closed or closed with a disruption in power. Thus, the switch sensing exit sign may allow its normal operation to occur without a need for a separate circuit that provides power at all times. It is to be appreciated that any switch sensing functionality mentioned herein may be used in conjunction with the switch sensing exit sign. In some embodiments, there may be a method included in the switch sensing exit sign to control the brightness of the switch sensing exit sign to conserve battery life.

In embodiments, a Switch Sensing Power Outage Light Fixture comprising of a light source, an integrated battery, a recharge component, a connection to external power and the switch sensing functionality may be designed in a housing to have the switch sensing functionality operate the light source based on the state of the external power and the state of the controlling switch or device. In embodiments, the light source may be LED, fluorescent, incandescent or the like. In one embodiment, the Switch Sensing Power Outage Light Fixture may operate as a normal light where turning the controlling switch or device on, off, dimming or similar control when there is not a disruption of power however when there is a disruption of power if the switch sensing functionality detects that the switch is closed, it may use the integrated battery as a power source to illuminate the light source. The normal state of the Switch Sensing Power Outage Light Fixture may be that the light source is not illuminated. In those embodiments, the light source may only be illuminated when a disruption of power is detected and the switch is detected such as it intends to apply power to the lighting fixture. The Switch Sensing Power Outage Lighting Fixture may detect the state of a controlling switch or device remotely and the Switch Sensing Power Outage Lighting Fixture may illuminate the light source independent of the state of the other lighting devices based on the state of the switch and power on the circuit. In some embodiments, the Switch Sensing Power Outage Light Fixture may contain a light source, a driver for the light source, a connection to the power circuit, an embedded power source, the ability to sense the state of one or more controlling devices and a control facility to manage the operation of the device. In one embodiment, the Switch Sensing Power Outage Lighting Fixture may be in a housing that contains three 1 W LEDs, an LED driver, a connection to AC power on the circuit it is monitoring, an integrated rechargeable battery, a recharging component, switch sensing circuitry and a processor to act as the control facility to take the detected switch sense and state of power delivered on the circuit and illuminate the LEDs upon certain conditions situated in the same housing. The Fixture may have an electrical circuit to allow an electrical ORing of the power sources or alternatively may have an electrical circuit allowing the control facility to select the power source for the light source. The Switch Sensing Power Outage Lighting Fixture may be installed and operate as a light normally controlled by a wall switch. When the wall switch is on and power is available, the Switch Sensing Power Outage Lighting Fixture may illuminate its light source powered by the AC power. When the wall switch is off, the Switch Sensing Power Outage Lighting Fixture may not illuminate its light source. The processor may control the Switch Sensing Power Outage Lighting Fixture to implement any function described herein for battery backup lighting capable of detecting the state of the controlling switches or devices. The switch sensing circuitry in the Switch Sensing Power Outage Lighting Fixture may not need external components to detect the state of the switch and from a detection of the difference in electrical characteristics at its external power input be capable of determining the state of a controlling switch or device. In embodiments, a system may be comprised of a Switch Sensing Power Outage Lighting Fixture and a power outage detector built into a wall switch or controlling device. The switch sense capability built into a lighting fixture with a power outage detector built into a wall switch allows the Switch Sensing Power Outage Lighting Fixture to detect a power outage prior to an open wall switch via the power outage detector. When the power outage detector presents an impedance or other electrical characteristic that the Switch Sensing Power Outage Lighting Fixture may detect as an additional level, it may allow the control facility to add a state to transition to such that when the switch is open and power is not present prior to the switch, the Switch Sensing Power Outage Lighting Fixture may illuminate its light source. The switch sensing sensor and control facility may be able to set multiple thresholds to allow measurements to indicate different conditions of the electrical characteristics of the electrical circuit where the Fixture resides to indicate different states of the electrical circuit and controlling devices.

In embodiments a system may be comprised of a power outage detector and a switch sense capable device such that the power outage detector may sense the state of power prior to a controlling switch or device and present an impedance or other electrical characteristic that the switch sense capable device may detect as a 3rd level allowing the switch sense capable device to transition to a state based on the state of the power outage detector. In such an embodiment, when the controlling switch or device is open and power is not present prior to the switch, the switch sensing capable device may cause a transition to a new state such as to be powered by a local or integrated power source when the controlling switch or device is open and power is not detected prior to the switch via the power outage detector. Thus, the switch sense capable device may detect three separate states with respect to the electrical characteristics it may measure. It may measure electrical characteristics that indicate controlling switch or device open, controlling switch or device closed or controlling switch or device open with no power prior to the controlling switch or device.

In embodiments, a switch sensing LED light fixture may be comprised of a processor with internal programmable dimming control capability, a connection to external power, a detection circuit to detect whether external power may be present, a switch sense circuit, an integrated battery and an LED lights source. In such an embodiment, the processor may control the intensity of the light source to extend the amount of time in which usable light may be available during a power outage. In some embodiments, the switch sensing LED light fixture may contain intelligence to detect the battery capacity level and adjust the light intensity level to extend the amount of time there is usable light out of the switch sensing LED light fixture. This may take advantage of the characteristic of batteries that at lower continuous current levels the rate of battery drain will be lower. By way of an example, if there is a short power outage, the initial light intensity level may be a high level, however after some amount of battery drain over some period of time, the light intensity level may be dropped to a lower level requiring less continuous current from the batteries, extending the amount of time the light source may run on batteries (anticipating that the power outage may last a long period of time).

In embodiments of lighting devices containing the switch sensing functionality, the switch sense function may contain the ability to measure the electrical characteristics of the building infrastructure supplying power to the switch sensing lighting device. The electrical characteristics may include the electrical response of the circuitry in the power distribution or a branch circuit including the connection to the secondary winding of the transformer supplying power to a building, through the circuit breaker box and through the wiring to every device that may be connected in parallel in the power distribution in a residence, office building etc. On an individual lighting circuit, there may be a power feed to one or more controlling switches or devices that control applying power to the devices on that lighting circuit. Thus, on the downstream side of the switch e.g., on the side of the switch electrically connected to the circuit breaker, all electrical devices are in parallel with one another. In the residential case, this includes other lighting devices, appliances like refrigerators, heaters, televisions, computers and the secondary coil of the transformer when power enters the building. On the upstream side of the switch e.g., on the side of the switch electrically connected to the lighting circuit, all of the electrical and lighting devices connected to the lighting circuit are present. As viewed from the lighting device containing the switch sensing functionality, the electrical characteristics that can be detected such as resistance, capacitance, inductance, impedance discontinuities, responses to generated signals etc are different depending on the state of the controlling switches or devices that control applying power to the devices on the lighting circuit. By way of an example, a wall switch controlling a lighting circuit may have a closed or open position either applying power to the lighting circuit or not applying power to the lighting circuit. If the switch is open, a lighting device containing the switch sensing functionality may detect or measure at its input power connection the electrical characteristics of the devices on the upstream side of the switch for example the incandescent, CFL or LED light bulbs, ballasts, ceiling fans, lighting fixtures, alternate forms of control and the like. If the switch is closed, a lighting device containing the electrical characteristics of the electrical devices, appliances, lighting devices etc on the downstream side of the switch will modify the electrical characteristics of the circuit as detected or measured at the input power connection of the lighting device. The change in electrical characteristics as seen at the input power connection of the lighting device may be due to the electrical characteristics of all of the devices added in both upstream and downstream of the switch contributing to present a different electrical circuit to the lighting device. The difference in electrical characteristics with the switch open and closed allows a lighting device with the switch sensing functionality to determine whether the switch is open or closed without a change or modification the existing infrastructure. The sensor within the lighting device may make the measurement or detection of the electrical characteristics and the control facility may act on that information along with other configuration or programming information to control operation of the lighting device. Embodiments of lighting devices containing the switch sensing functionality eliminate the need for retrofitting, altering the exiting circuitry in the building and provide an out-of-the-box or plug-and-play solution where the entire functionality may be installed with the installation of the lighting device itself.

In embodiments of grid shifting and switch sensing lighting devices, a Grid Shifting Lighting Device with Switch Sensing Capability may be comprised of a connection to external power, a rechargeable energy storage device, a light source, a sensor for detecting the state of a power delivery switch, a control facility and a housing. In embodiments, a user may turn on, off, dim or control the light source using the power delivery switch. When the sensor and control facility detect that the power delivery switch intends to apply external power to the lighting device and external power is not detected by the lighting device, the control facility may apply power to the light source from the rechargeable energy storage device. The Grid Shifting Lighting Device with Switch Sensing Capability may be powered by the rechargeable energy storage device during a power outage. In cases such as a scheduled power outage or rolling blackout, the Grid Shifting Lighting Device with Switch Sensing Capability may provide illumination for an extended period of time allowing normal operation during the outage. By way of an example, a manufacturing facility may be able to continue operation during a scheduled power outage using the Grid Shifting Lighting Device with Switch Sensing Capability which would automatically switch over to the rechargeable energy storage device when the power outage is detected. The power deliver switch will continue to control the lighting device even during the power outage. In embodiments, the lighting device may be programmable, may have a real time clock, may be AC or externally powered and controlled by a wall switch allowing normal light operation, may allow the battery to be recharged while AC power or external power is applied or when power goes out or may allow a user control the light source from the RF remote/controller while powered by the battery power source. In some embodiments, the Grid Shifting Lighting Device with Switch Sensing Capability may have an interface to program the Lighting Device allowing the Lighting Device to be programmed to operate based on time of day. In some embodiments, a wireless receiver in the lighting device allows a user to dim a light or select from multiple lighting levels via a wireless remote control to conserve battery power and thus extend the amount of time that usable light is available. In some embodiments, the power delivery switch contains a motion sensor such that the switch sensing function may detect from the power delivery switch whether motion has been detected to determine whether to illuminate the light source. In such a case, the motion sensor switch may contain a battery such that it may continue to operate during the power outage. The claimed subject matter may be designed in any size or shape housing to meet the requirements of any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g. T4, T5, T8, circular etc.) or down light assembly (e.g. recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting), or the like. It is to be appreciated that any combination of wireless control mentioned herein may be used in conjunction with the claimed subject matter.

In embodiments containing the switch sensing functionality, the frequency response of a pulse or signal generated by switch sense circuitry may indicate the position of the controlling switch or devices. In embodiments of the switch sensing functionality containing a sense resistor, a spectrum analysis of the pulse or signal after the sense resistor may provide information to determine the state of the controlling switch. The response of the pulse or signal to the electrical characteristics of the different configurations seen based on the state of the controlling switches or devices may be detected or measured as different based on the state of the switch. By way of an example, some frequency band in the pulse or signal may be significantly attenuated by the electrical characteristics of the power feed to the switch sensing device when the switch is in one state whereas when the switch is in another state the pulse or signal may not be attenuated.

In embodiments containing the switch sensing functionality, the switch sensing function may be in a separate housing from the lighting device. In some embodiments, the switch sensing sensor may be in a separate housing. In some embodiments, the switch sensing sensor and control facility may be in a separate housing. The components of a switch sensing lighting device may be arranged in any manner to implement the switch sensing function for a lighting device and the various arrangements may require electrical or mechanical interfacing between different housings, enclosures, electrical apparatuses etc to implement the switch sensing function for the lighting device.

In some embodiments, an intelligent wall switch may contain one or more environmental sensor and an integrated power source such that the intelligent wall switch may detect an environmental condition and control a lighting device even in the absence of external power at the device. In one embodiment, a motion sensing intelligent wall switch may contain a motion sensor and an integrated rechargeable battery such that a switch sensing circuit inside a lighting device may detect from the motion sensing intelligent wall switch whether motion has been detected to determine whether to illuminate the light source. In such an embodiment, the motion sensor switch contains a battery such that it may continue to operate during the power outage. In such an embodiment, the motion sensing intelligent wall switch may open and close a switch to the external power source when motion is detected however when the switch is closed and external power is not present, the switch sensing circuit inside the lighting device will detect this as a power outage condition and illuminate the light source powered by its local power source. In another embodiment, an intelligent wall switch with an integrated power source and a dimming capability may continue to operate a switch sensing lighting device during a power outage. In such a case, the switch sensing circuit may detect an electrical characteristic that it may associated with an intensity level of the light source such that the control facility in the switch sensing lighting device may PWM control, amplitude control, constant current control etc the light source to achieve the desired light intensity level. In embodiments, a light sensor may be present in the intelligent wall switch and provide a daylight harvesting function during a power outage where the light intensity is set based on the ambient light level detected such that the ambient light plus the light generated by the light source maintain a constant light level. This would be done in conjunction with a switch sensing lighting device such that the switch sensing circuit may detect electrical characteristics of the circuit that represent the light intensity level required of the switch sensing lighting device to maintain the proper light intensity level.

Referring to FIG. 15, the present invention may provide a lighting system capable of reducing the power consumption from the power company but maintaining the normal light intensity levels. The lighting system 1500 may be comprised of a lighting source 1502, a connector 1504 in electrical association with the lighting source and an external power source 1506, an energy storage device 1508, an input device 1510 and a grid-shifting controller 1512. The light intensity level of the lighting source 1506 may be controlled by the grid-shifting controller 1512 such that some amount of power may be consumed from the external power source 1506 and some amount of power may be consumed from the energy storage device 1508. The purpose for consuming some amount of power from the energy storage device 1508 is to reduce the amount of power consumed from the external power source 1506 in times when a reduction in demand of power from the external power source may be advantageous. By way of an example, a power supply for an LED light fixture may have a connection to grid power, a connection to an LED light source and a rechargeable battery. An LED driver circuit may convert grid power to a drive for the LED light source and there may be a drive circuit to convert the energy storage device 1508 to drive the LED light source. A switching circuit or power sharing mechanism may allow for the sharing of power between the one or more power sources as mentioned herein. The connection to grid power may be used to recharge the energy storage device 1508. In another example, the lighting system may include a ballast and a fluorescent light source where the ballast is comprised of the components described herein. In embodiments of the lighting system 1500, the grid shifting controller 1512 may be configured to provide an output based on information received via the input device 1510 wherein the grid-shifting controller 1512 may be further configured to identify the presence of a load indicator signal received via the input device 1510, to determine whether the load indicator signal indicates a load-reducing state and to discharge the energy storage device 1508 to maintain the light intensity of the lighting source 1502 during a load-reducing state. In embodiments, the load indicator signal may indicate a load-reducing state to discharge the energy storage device 1508 to maintain any lighting intensity level designated by the load indicator signal wherein the light intensity level may be lower or higher than the normal light intensity level. The input device 1510 may communicate with respect to the load-reducing state or any related status or control with an external device to configure or program the grid-shifting controller 1512. The method of communication may be by wired connection over a power distribution network, for example on the AC power lines (X10, INSTEON, Broadband over Power Lines, proprietary communication scheme etc), or wirelessly through a wireless interface (dedicated RF communication link, ZIGBEE, WIFI, ENOCEAN, BLUETOOTH etc). The method of communication may be wireless through a wide area network. In one embodiment, the lighting device capable of maintaining light intensity while reducing power consumption from the grid may contain an input device capable of connecting to and communicating over a 2.5G, 3G or 4G network by which it may receive commands and transmit responses over the wide area network with the parameters of the grid shifting action as well as any timing information related to the behavior of the lighting device with respect to grid shifting. By way of an example, street lights within the city limits of a town that are capable of maintaining light intensity while reducing power consumed from the grid contain a 2.5G data modem and may receive a command over the 2.5G connection to reduce power consumption for a given time period. The components of the lighting system 1500 may be contained within one or more housings as needed to implement the lighting system 1502. The claimed subject matter may be designed in any size or shape housing to meet the requirements of any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g. T4, T5, T8, circular etc.) or down light assembly (e.g. recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting), ballast, lighting power supply, driver, LED driver, inline inverter or the like. Any combination of wireless control mentioned herein may be used in conjunction with the claimed subject matter.

The grid-shifting controller 1512 may be further configured to determine whether the load indicator signal indicates a non-load-reducing state and recharge the energy storage device 1508 during the non-load-reducing state. The lighting source 1502 may be configured to receive power from both the external power source 1506 and the energy storage device 1508 during the load-reducing state. The lighting source 1502 may be configured to receive power from only the energy storage device 1508 during the load-reducing state. The input device 1510 may be configured to receive one or more control signals and provide the one or more control signals to the grid-shifting controller 1512. There may be one or more control signals generated by an external controller such as a demand response system, a utility company, a building management system or the like. The one or more control signals may be received wirelessly from a network, via power lines or through a wired network connection. By way of an example, the lighting device capable of maintaining light intensity while reducing power consumption from the grid may receive a demand response signal from the utility in the form of packetized data via a communication network wherein the packetized data contains the parameters and timing of the demand response action required by the lighting device. In some examples, the utility may communicate with an intermediate device that may translate the packetized data from one communication network to another communication network such that when received by the lighting device it may interpret the command originating from the utility to implement the demand response action.

In an embodiment, the lighting system 1500 may be comprised of a lighting source 1502, a connector 1504 in communication with an external power source 1506, an energy storage device 1508, an input device 1510 and a grid-shifting controller 1512 where the lighting source 1502 may be integrated with the other components in a lighting fixture, light bulb, lighting device or the like that has a connection to the external power source 1506. The grid-shifting controller 1512 may be configured to provide an output based on information received via the input device 1510 wherein the grid-shifting controller 1512 is further configured to manage power usage of the lighting source 1502 based on one or more of a signal generated by the input device 1510, an internal timer or an internal clock. The management of the power usage of the lighting source 1502 may include selection of a power source from which the lighting source 1502 receives power. The grid-shifting controller 1512 may be further configured to control when the energy storage device 1508 is charging. The management of the power usage of the lighting source 1502 may include controlling of an amount of load shared by the external power source 1506 and the energy storage device 1508. The claimed subject matter may be designed in any size or shape housing to meet the requirements of any standard size bulb (e.g. PAR30, PAR38, A19, R30, MR16 etc), non-standard size bulb, fixture, compact fluorescent bulb, fluorescent bulb or lamp (e.g., T4, T5, T8, circular etc.) or down light assembly (e.g., recessed fixtures, fluorescent fixtures or down light fixtures for residential, commercial or industrial lighting) or the like. Any combination of wireless control mentioned herein may be used in conjunction with the claimed subject matter. 

The invention claimed is:
 1. A system, comprising: a remote control comprising: a transmitter; one or more first processors; and first memory storing first instructions that, when executed by the one or more first processors, cause the one or more first processors to perform first operations comprising transmitting, using the transmitter, a control signal representing a command to change to an illumination state; and a lighting device comprising: a light source; a receiver; one or more second processors; and second memory storing second instructions that, when executed by the one or more second processors, cause the one or more second processors to perform second operations comprising: receiving, using the receiver, the control signal; determining, using the control signal, that the remote control is proximate to the lighting device; and after determining that the remote control is proximate to the lighting device, causing the light source to change to the illumination state.
 2. The system of claim 1, wherein the illumination state includes at least one of an on state, an off state, a brightness level, a color, or an illumination timing.
 3. The system of claim 1, the second memory storing third instructions that, when executed by the one or more second processors, cause the one or more second processors to perform third operations comprising: determining a time of arrival of the control signal, wherein determining that the remote control is proximate to the lighting device comprises determining, using the time of arrival, that the remote control is proximate to the lighting device.
 4. The system of claim 1, the second memory storing third instructions that, when executed by the one or more second processors, cause the one or more second processors to perform third operations comprising: determining a signal strength associated with the control signal, wherein determining that the remote control is proximate to the lighting device comprises determining, using the signal strength, that the remote control is proximate to the lighting device.
 5. The system of claim 1, the second memory storing third instructions that, when executed by the one or more second processors, cause the one or more second processors to perform third operations comprising: storing data indicating a range, wherein determining that the remote control is proximate to the lighting device comprises determining, using the control signal, that the remote control is within the range to the lighting device.
 6. The system of claim 1, the second memory storing third instructions that, when executed by the one or more second processors, cause the one or more second processors to perform third operations comprising: receiving, using the receiver, an additional control signal, the additional control signal representing an additional command to change to an additional illumination state; determining, using the additional control signal, that the remote control is not proximate to the lighting device; and ceasing from causing the light source to change to the additional illumination state.
 7. The system of claim 1, wherein the remote control further comprises: a first button; and a second button, and wherein the first memory stores third instructions that, when executed by the one or more first processors, cause the one or more first processors to perform third operations comprising: receiving a first input using the first button; after receiving the first input, transmitting, using the transmitter, an additional control signal at a first power level; and receiving a second input using the second button, wherein transmitting the control signal comprises, after receiving the second input, transmitting, using the transmitter and to the lighting device, the control signal at a second power level.
 8. A first electronic device comprising: a light source; a receiver; one or more processors; and memory storing instructions that, when executed by the one or more processors, cause the one or more processors to perform operations comprising: receiving, using the receiver, a signal from a second electronic device, the signal representing a command to change the light source to a state; determining, using the signal, that the first electronic device is proximate to the second electronic device; and after determining that the first electronic device is proximate to the second electronic device, causing the light source to change to the state.
 9. The first electronic device of claim 8, wherein the second electronic device is one of a remote control, a remote sensor, a wireless lighting device, or a power outage device.
 10. The first electronic device of claim 8, wherein the command to change the light source to the state includes at least one of: a first command to change the light source to an on state; a second command to change the light source to an off state; a third command to change a brightness of the light source; a fourth command to change a color of the light source; or a fifth command to change an illumination timing of the light source.
 11. The first electronic device of claim 8, the memory storing further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: determining a time of arrival associated with the signal, wherein determining that the first electronic device is proximate to the second electronic device comprises determining, using the time of arrival, that the first electronic device is proximate to the second electronic device.
 12. The first electronic device of claim 11, further comprising: a first button; and a second button, wherein the memory stores further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: receiving a first input using the first button; after receiving the first input, transmitting, using the transceiver, a third signal at a first power level; and receiving a second input using the second button, wherein transmitting the second signal comprises, after receiving the second input, transmitting, using the transceiver and to the second electronic device, the second signal at a second power level.
 13. The first electronic device of claim 11, further comprising: a first button; and a second button, wherein the memory stores further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: receiving a first input using the first button; after receiving the first input, transmitting, using the transceiver, a third signal using a first communication channel; and receiving a second input using the second button, wherein transmitting the second signal comprises, after receiving the second input, transmitting, using the transceiver and to the second electronic device, the second signal using a second channel.
 14. The first electronic device of claim 8, the memory storing further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: receiving, using the receiver, an additional signal from at least one of the second electronic device or a third electronic device, the additional signal representing an additional command to change the light source to an additional state; determining, using the additional signal, that the first electronic device is not proximate to the at least one of the second electronic device or the third electronic device; and ceasing from causing the light source to change to the additional illumination state.
 15. The first electronic device of claim 8, the memory storing further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: determining signal strength associated with the signal, wherein determining that the first electronic device is proximate to the second electronic device comprises determining, using the signal strength, that the first electronic device is proximate to the second electronic device.
 16. The first electronic device of claim 8, the memory storing further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: storing data indicating a range, wherein determining that the first electronic device is proximate to the second electronic device comprises determining, using the signal, that the first electronic device is proximate to the second electronic device.
 17. A first electronic device comprising: a transceiver; one or more processors; and memory storing instructions that, when executed by the one or more processors, cause the one or more processors to perform operations comprising: receiving, using the transceiver, a first signal from a second electronic device; determining a signal strength of the first signal; determining, using the signal strength, that the first electronic device is proximate to the second electronic device; and after determining that the first electronic device is proximate to the second electronic device, transmitting, using the transceiver, a second signal to the second electronic device, the second signal representing a command to change a state of a light source.
 18. The first electronic device of claim 17, wherein the first electronic device includes at least one of a remote control, a remote sensor, a lighting device, or a power outage device.
 19. The first electronic device of claim 17, wherein the command to change the state of the light source includes at least one of: a first command to change the light source an on state; a second command to change the light source to an off state; a third command to change a brightness of the light source; a fourth command to change a color of the light source; or a fifth command to change an illumination timing of the light source.
 20. The first electronic device of claim 17, the memory storing further instructions that, when executed by the one or more processors, cause the one or more processors to perform further operations comprising: receiving, using the transceiver, a third signal from at least one of the second electronic device or a third electronic device; determining an additional signal strength of the third signal; determining, using the additional signal strength, that the first electronic device is not proximate to the at least one of the second electronic device or the third electronic device; and ceasing from transmitting, using the transceiver, a fourth signal to the at least one of the second electronic device or the third electronic device. 